Information processing apparatus, managing method, computer-readable recoding medium storing managing program therein, and electronic apparatus

ABSTRACT

The information processing apparatus includes: a connection unit which an electronic apparatus is adapted to be communicably coupled to; a connection detecting unit which detects coupling of the electronic apparatus to the connection unit; a timer which measures a time duration that elapses under a connection state, in which the electronic apparatus is engaged; and an alerting unit which alerts a user of the information processing apparatus when it is detected by the timer that a predetermined time duration elapses. With this arrangement, it is possible to prevent forgetting to disengage the electronic apparatus from the information processing apparatus, and the convenience of handling of the electronic apparatuses is improved.

TECHNICAL FIELD

The present invention relates to the technology for using an electronic apparatus such as a USB memory and an information processing apparatus with connection therebetween.

BACKGROUND ART

Recently, portable data storage apparatuses, such as a USB (Universal Serial Bus) memory, provided with (i) a connection terminal (USB connector) for connection thereof with a computer and (ii) a memory operable to store data therein, have been widely used.

Such a USB memory is carried by a user and connected to a USB port of a computer at the place where the user is (the place to which the user has moved) by means of inserting the connector (USB connector) of the USB memory into the USB port. The user accesses the internal memory of the USB memory from the computer to perform data reading, data storing, data deleting or the like to the internal memory of the USB memory apparatus.

Patent Document 1: Published Japanese Translation of a PCT Application No. 2004-519791

DISCLOSURE OF THE INVENTION Issue(s) to be Solved by the Invention

Such previous information processing apparatuses, however, have problems as follows: after using a USB memory with insertion thereof into the information processing apparatus, the USB memory is sometimes left in a state where the USB memory is being inserted to the information processing apparatus, so that it can occur that the USB memory is left behind.

Such an occurrence of leaving a USB memory behind or loss of it will result in loss of the data stored in the memory. Moreover, in a case where the USB memory stores confidentially important data, there is a possibility of leakage of this confidential data.

Further, in order to improve the confidentiality of data stored in a USB memory, the above patent document 1, for example, discloses a method for constructing a USB memory with an authentication module employing a fingerprint sensor and a non-volatile memory. In the patent document 1, the fingerprint sensor reads the fingerprint of a user, and then permits the user to access the non-volatile memory when the read-out fingerprint matches any of the fingerprints having been registered beforehand. Contrarily, when the read-out fingerprint does not match any of the registered fingerprint, access to the non-volatile memory is refused. With such a method, the data security in the USB memory is realized.

However, it is impossible for the USB memory of the patent document 1 to prevent a USB memory from being left behind. In addition, since an authentication module must be provided for the USB memory, a problem is caused of increasing in manufacturing cost of such USB device.

The present invention is proposed with the foregoing problems in view, and one object of the present invention is to make it possible to prevent electronic apparatuses from being left in a connection state thereof with information processing apparatuses. An other object of the invention is to improve the convenience of handling of the electronic apparatuses.

Means to Solve the Issue(s)

In order to accomplish the above objects, as a generic feature of the present invention, there provided is an information processing apparatus, comprising: a connection unit to which an electronic apparatus is adapted to be communicably coupled; a connection detecting unit which detects coupling of the electronic apparatus to the connection unit; a timer (second timer) which measures a time duration that elapses under a connection state, in which the electronic apparatus is coupled; and an alerting unit which alerts a user of the information processing apparatus when it is detected by the timer that a predetermined time duration elapses.

As a preferred feature, the information processing apparatus further comprises: an alert controlling unit which is capable of restraining the alert given by the alerting unit, and the alert controlling unit restrains the alert given by the alerting unit, if a user of the information processing apparatus is a specific authorized user relating to the information processing apparatus when the timer detects that the predetermined time duration elapses.

As another preferred feature, the information processing apparatus further comprises: an unused state detecting unit which detects transition of the information processing apparatus to an unused state thereof by the user, and the alerting unit gives the alert when the unused state detecting unit detects the transition of the information processing apparatus to the unused state thereof.

As a yet another preferred feature, the unused state detecting unit detects the transition of the information processing apparatus to the unused state thereof by means of detecting power-off of the information processing apparatus.

As a still another preferred feature, the unused state detecting unit detects that the transition of the information processing apparatus to the unused state thereof by means of detecting shifting of the information processing apparatus into a power-saving operation mode.

As a further preferred feature, the information processing apparatus further comprises: a user detecting unit which detects existence of a user of the information processing apparatus, and the unused state detecting unit detects the transition of the information processing apparatus to the unused state thereof at the time the existence of the detected user is not anymore detected by the user detecting unit.

As a yet further preferred feature, the information processing apparatus further comprises: a first user confirming unit which confirms that a user of the information processing apparatus is the specific authorized user relating to the information processing apparatus.

As a still further preferred feature, the alert controlling unit restrains an alert given by the alerting unit when the electronic apparatus coupled to the information processing apparatus is an electronic apparatus of the specific authorized user.

As another generic feature, in the present invention, there provided is a managing method for use in an information processing apparatus including a connection unit to which an electronic apparatus is adapted to be communicably coupled, the method comprising: (a) detecting coupling of the electronic apparatus to the connection unit; (b) measuring an elapse time duration that elapses under a connection-established state, in which the electronic apparatus is coupled to the electronic apparatus, from when the connection with the electronic apparatus is detected in the step (a); and (c) giving a user of the information processing apparatus an alert when it is detected that a predetermined time duration (second predetermined time duration) elapses in the step (b).

As a preferred feature, the managing method further comprises: (d) restraining the alert given in the step (c). In the step (d), the alert given in the step (c) is restrained, if a user of the information processing apparatus is confirmed to be a specific authorized user relating to the information processing apparatus when it is detected that the predetermined time duration elapses in the step (b).

As another preferred feature, the managing method further comprises: (e) detecting transition of the information processing apparatus to an unused state thereof by the user. The alert is given in the step (c) when the transition of the information processing apparatus to an unused state thereof is detected in the step (e).

As yet another preferred feature, in the step (e) of the managing method, the transition of the information processing apparatus to the unused state thereof is detected by means of detecting power-off of the information processing apparatus.

As still another preferred feature, in the step (e) of the managing method, the transition of the information processing apparatus to the unused state thereof is detected by means of detecting shifting of the information processing apparatus into a power-saving operation mode.

As a further preferred feature, the managing method further comprises: (f) detecting existence of a user of the information processing apparatus. The transition of the information processing apparatus to the unused state thereof is detected in the step (e) at the time the existence of the user detected in the step (f) is not detected anymore.

As a yet further preferred feature, the managing method further comprises: (g) confirming that a user of the information processing apparatus is the specific authorized user.

As yet another generic feature, there provided is a computer-readable recording medium in which a managing program for a computer to execute a managing function is recorded, wherein the program instructs the computer, having a connection unit to which an electronic apparatus is adapted to be communicably coupled, to execute the steps of: (a) detecting coupling of the electronic apparatus to the connection unit; (b) measuring an time duration that elapses under a connection-established state, in which the electronic apparatus is coupled to the electronic apparatus, from when the connection with the electronic apparatus is detected in the step (a); and (c) giving a user of the information processing apparatus an alert when it is detected that a predetermined time duration (second predetermined time duration) elapses in the step (b).

As a preferred feature, the managing program further instructs the computer to execute (d) restraining of the alert given in the step (c), and in the step (d), the alert given in the step (c) is restrained, if a user of the information processing apparatus is confirmed to be a specific authorized user relating to the information processing apparatus when it is detected that the predetermined time duration elapses in the step (b).

As another preferred feature, the managing program further instructs the computer to execute (e) detecting of transition of the information processing apparatus to an unused state thereof by the user, and the alert is given in the step (c) when the transition of the information processing apparatus to an unused state thereof is detected in the step (e).

As yet another preferred feature, the transition of the information processing apparatus to the unused state thereof is detected by means of detecting power-off of the information processing apparatus at the time the managing program instructs the computer to execute the step (e).

As still another preferred feature, the transition of the information processing apparatus to the unused state thereof is detected by means of detecting shifting of the information processing apparatus into a power-saving operation mode at the time the managing program instructs the computer to execute the step (e).

As a further preferred feature, the managing program further instructs the computer to execute (f) detecting existence of a user of the information processing apparatus, and the transition of the information processing apparatus to the unused state thereof is detected in the step (e) at the time the existence of the user detected in the step (f) is not anymore detected.

As a yet further preferred feature, the managing program further instructs the computer to execute (g) confirming that a user of the information processing apparatus is the specific authorized user relating to the information processing apparatus.

As still another generic feature, there provided is an electronic apparatus having a communication unit for communicably coupling the electronic apparatus to an information processing apparatus, the electronic apparatus comprising: a connection detecting unit which detects coupling of the electronic apparatus to the information processing apparatus via the communication unit; a timer which measures an time duration that elapses under a connection-established state, in which the electronic apparatus is coupled to the information processing apparatus, from when the connection detecting unit detects the connection of the communication unit to the information processing apparatus; and an alerting unit which gives a user of the electronic apparatus an alert when it is detected by the timer that a predetermined time duration elapses.

As a preferred feature, the electronic apparatus further comprises: an alert controlling unit which is capable of restraining the alert given by the alerting unit, the alert controlling unit restraining the alert given by the alerting unit, if a user of the information processing apparatus is a specific authorized user relating to the electronic apparatus when the timer detects that the predetermined time duration elapses.

As another preferred feature, the electronic apparatus further comprises: a user confirming unit which confirms that a user of the information processing apparatus is a specific authorized user relating to the information processing apparatus.

As yet another preferred feature, the alert controlling unit restrains the alert given by the alerting unit in a case where the electronic apparatus is an electronic apparatus of the specific authorized user.

EFFECTS OF THE INVENTION

According to the present invention, at least any one of the following effects and benefits are obtained.

(1) Since it is possible to make a user of the electronic apparatus recognize that the electronic apparatus is being in use, leaving the electronic apparatus behind or the like can be prevented.

(2) Since it is possible for a user to know that the remaining battery amount becomes small, the eventualities caused by the shortage of the remaining battery can be prevented.

(3) The reliability of the electronic apparatus is improved.

(4) Since the battery is rechargeable, the convenience of the electronic apparatus is improved.

(5) The reliability is improved.

(6) The data security is improved, and the leakage of confidential information is prevented.

(7) It is possible to prevent a user from troublesome feeling brought about by being alerted.

(8) It is possible to protect the data in the electronic apparatus and the information processing apparatus from being illegally used by a third person.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram schematically showing a functional construction of a USB (Universal Serial Bus) memory according to a first embodiment of the present invention;

FIG. 2 is a diagram schematically showing a hardware construction of the USB memory according to the first embodiment of the present invention;

FIG. 3 is a diagram schematically showing a hardware construction of a PC to which the USB memory is coupled according to the first embodiment of the present invention;

FIG. 4 is a flowchart for describing processing for uncapping the cap of the USB memory according to the first embodiment of the present invention;

FIG. 5 is a flowchart for describing processing for connecting of the USB memory to the PC according to the first embodiment of the present invention;

FIG. 6 is a diagram schematically showing a first modified example of the functional construction of the USB memory according to the first embodiment of the present invention;

FIG. 7 is a diagram schematically showing a second modified example of the functional construction of the USB memory according to a second modified example of the first embodiment of the present invention;

FIG. 8 is a diagram schematically showing a functional construction of a USB (Universal Serial Bus) memory according to a second embodiment of the present invention;

FIG. 9 is a flowchart for describing processing for uncapping the cap of the USB memory according to the second embodiment of the present invention;

FIG. 10 is a flowchart for describing processing for coupling of the USB memory to the PC according to the second embodiment of the present invention;

FIG. 11 is a diagram schematically showing functional constructions of a PC and a USB memory according to a third embodiment of the present invention;

FIG. 12 is a diagram schematically showing a functional construction of a USB memory according to a fourth embodiment of the present invention;

FIG. 13 is a diagram schematically showing a functional construction of a USB memory and a PC which is used with the USB memory connected thereto according to a fifth embodiment of the present invention;

FIG. 14 is a diagram schematically showing a functional construction of a USB memory and a PC which is used with the USB memory connected thereto according to a sixth embodiment of the present invention.

DESCRIPTION OF REFERENCE CHARACTERS

-   -   1 a, 1 b, 1 c, 1 d, 1 e, 1 f, 1 g, and 1 h . . . USB memory         (electronic apparatus)     -   10 a, 10 b, 10 c, 10 d, 10 e, 10 f, 10 g, and 10 h . . . main         body unit     -   11 . . . storage unit     -   12 and 45 . . . connection detector     -   13, 13-1, and 13-2 . . . first timer (timer)     -   14 . . . second timer     -   15, 15-1, 15-2, and 37 . . . alerting unit     -   16, 16-1, and 16-2 . . . switch (sensor)     -   17 . . . USB connector (communication unit, connection terminal)     -   18, 18-1, and 18-2 . . . battery measuring unit     -   19, 19-1, and 19-2 . . . battery     -   20 a, 20 b, 20 c, 20 d, and 20 f . . . cap (component)     -   30 a, 30 e, 30 g, and 30 h . . . PC (information processing         apparatus, computer)     -   32 . . . storage unit     -   33 . . . alert controller     -   34 . . . unused state detector     -   35 . . . user detector     -   36 . . . timer     -   38 . . . user confirming unit     -   39 . . . user information obtaining unit     -   40 . . . USB memory confirming unit     -   41 . . . copy inhibitor     -   42 . . . access inhibitor     -   43 . . . elapse time obtaining unit     -   44 . . . storage time limit setting unit     -   46 . . . managing unit     -   101 . . . microcomputer     -   102 . . . processor     -   103 . . . RAM     -   104 . . . control soft ROM     -   105 . . . timer     -   106 . . . USB interface     -   107 . . . Flash memory interface     -   108 . . . buzzer circuit     -   109 . . . cap detection switch     -   110 . . . flash memory     -   112 . . . power circuit     -   113 . . . charge circuit     -   191 . . . electrode     -   201 . . . engagement opening     -   301 . . . CPU     -   302 . . . ROM     -   303 . . . RAM     -   304 . . . display     -   305 . . . HDD (storage unit)     -   306 . . . keyboard     -   307 . . . mouse     -   308 . . . USB controller

BEST MODE FOR CARRYING OUT THE INVENTION

Preferred embodiments of the present invention will now be described with reference to the relevant accompanying drawings.

(A) First Embodiment

FIG. 1 is a diagram schematically showing a functional construction of USB (Universal Serial Bus) memory according to a first embodiment of the present invention.

As shown in FIG. 1, a USB memory (electronic apparatus) 1 a according to the first embodiment includes: a main body unit 10 a having a USB connector (communication unit, connection terminal) 17 and a storage unit 11; and a cap (component) 20 a which is formed in such a manner that it is removable from the USB connector 17. The USB connector 17 is inserted/connected to a USB port 31 of a PC (Personal Computer; information processing apparatus, computer) 30 a (see FIG. 3), the USB memory 1 a being thereby connected to the PC 30 a in a communicable manner therebetween. The PC 30 a accesses the storage unit 11 to perform processing such as reading, writing, and deleting of data or files (herein after will be simply called “data”). In this instance, this USB memory 1 a is also a portable storage apparatus.

As shown in FIG. 1, the main body unit 10 a of the USB memory 1 a includes: a storage unit 11; a connection detector 12; a first timer 13; a second timer 14; an alerting unit 15; a switch 16; a USB connector 17; a battery measuring unit 18; and a battery 19.

The storage unit 11 stores various kinds of data therein in such a manner that the stored data can be read out. The USB connector 17, which is a connector (male) formed in line with the Universal Serial Bus regulations, can be inserted/connected to a variety of types of electronic apparatuses (for example, the PC 30 a in the first embodiment) that are provided with USB ports 31 [USB connectors (female); see FIG. 3] formed in line with the same USB regulations.

The connection detector 12 detects that the main body unit 10 a of the USB memory 1 a is connected to the PC 30 a via the USB connector 17. In this instance, such detection of connection to the PC 30 a by the connection detector 12 can be realized by using a variety of types of already known methods. Further, upon detection that the USB memory 1 a is connected to the PC 30 a, the connection detector 12 outputs a signal (connection detection signal) informing as such to the second timer 14.

In the following description, connecting the main body unit 10 a of the USB memory 1 a to the PC 30 a via the USB connector 17 will sometimes be simply referred to as connecting the USB memory 1 a to the PC 30 a for the convenience of description.

The cap 20 a, which is engaged with the USB connector 17 when the USB memory 1 a is not being used, protects the USB memory 1 a and the USB connector 17 from physical and electrical stimulations and prevents the intrusion of dirt and dust. The cap 20 a is made from, for example, insulation material such as resin.

The cap 20 a has an engagement opening 201 which has a shape approximately the same as that of the USB connector 17 and into which the USB connector 17 can be inserted. The USB connector 17 is fit together with the engagement opening 201 by insertion, thereby being mounted to the USB connector 17. That is, the cap 20 a is constructed in such a manner that it is detachable from the USB connector 17, which makes the cap 20 a detachable from the main body unit 10 a (USB memory 1 a).

Further, in the USB memory 1 a according to the first embodiment, the switch 16 provided adjacent to the USB connector 17 of the main body unit 10 a is pushed down by a part of the cap 20 a or the like when the cap 20 a is mounted to the USB connector 17.

The switch (sensor) 16 detects an uncapped state of the cap 20 a in which the cap 20 a is uncapped from the USB connector 17. Upon detecting that the cap 20 a is uncapped from the USB connector 17 (falls in the uncapped state), the switch (sensor) 16 outputs a signal (an uncapped state detection signal) informing as such to the first timer 13.

The first timer 13 measures a time duration that elapses under a state in which the cap 20 a is uncapped, from when the switch 16 detects that the cap 20 a is uncapped. Upon reception of a disengaged state detection signal from the switch 16, the first timer 13 starts measuring (countdown). Then, upon elapse of a predetermined time duration (a first predetermined time duration), which has been set beforehand, the first timer 13 outputs a signal (first predetermined time detection signal) informing as such to the alerting unit 15, which will be described later.

The second timer 14 measures a time duration that elapses under a connection-established state, in which the USB connector 17 is connected to the PC 30 a, from when the connection detector 12 detects that the USB connector 17 is connected to the PC 30 a. Upon reception of a connection detection signal from the connection detector 12, the second timer 14 starts measuring (countdown). Then, upon elapse of a predetermined time (a second predetermined time duration), which has been set beforehand, the second timer 14 outputs a signal (second predetermined time duration detection signal) informing as such to the alerting unit 15, which will be described later.

The battery 19, which supplies electricity to each of the units, such as the alerting unit 15 which will be described later, of the main body unit 10 a of the USB memory 1 a, is formed by a rechargeable battery, to which electricity is chargeable.

A USB has a bus power (USB bus power) function of supplying electricity from the main body of the computer to peripheral equipment through a USB connector and a USB cable. According to the present embodiment, also, electricity is supplied from the PC 30 a to the main body unit 10 a through the USB connector 17 and the USB port 31 under a state in which the USB memory 1 a (main body unit 10 a) is connected to the PC 30 a.

Then, the battery 19 is automatically charged with electricity supplied from the PC 30 a via the USB connector 17 and the USB port 31 under a state in which the USB memory 1 a (main body unit 10 a) is connected to the PC 30 a.

The battery measuring unit 18 measures the remaining mount (battery amount) of the battery 19. When detecting that the remaining battery amount is not larger than a predetermined amount as a result of comparison between the measured remaining battery amount of the battery 19 and a predetermined amount having been set beforehand, the battery measuring unit 18 outputs a signal (remaining amount detection signal) informing as such to the alerting unit 15, which will be described below.

The alerting unit 15 gives a user of the USB memory 1 a an alert. The alerting unit 15 calls the user's attention by means of giving any stimulation to the user's five senses (of seeing, hearing, touching, tasting, and smelling) or the like. In this instance, in the present embodiment, a description will be made of an example in which the alerting unit 15 generates a sound at a specific frequency (alarming sound), thereby giving the user an alert effecting to the user's sense of hearing.

Then, the alerting unit 15 gives an alert when the first timer 13 detects that the first predetermined time duration elapses. Concretely, the alerting unit 15 gives an alert when it receives the first predetermined time duration detection signal from the first timer 13.

Further, the alerting unit 15 gives an alert also when the second timer 14 detects that a second predetermined time duration elapses. Concretely, upon reception of a second predetermined time duration detecting signal from the second timer 14, the alerting unit 15 gives an alert.

Still further, the alerting unit 15 gives an alert also when it is detected that the remaining amount of the battery 19 is not larger than a predetermined amount. Concretely, upon reception of a remaining amount signal from the battery measuring unit 18, the alerting unit 15 gives an alert.

In this instance, in the USB memory 1 a according to the first embodiment, the alerting unit 15 generates an alarming sound, thereby giving a user an alert, in a case where the first predetermined time duration detection signal is received from the first timer 13, and in a case where the second predetermined time duration detection signal is received, and in a case where the remaining amount of the battery 19 is detected to be not larger than a predetermined amount. In the above cases, the generated alarming sounds can be the same or different from each other (at different frequencies). Further, the same alarming sound can be generated in any of the parts of the cases.

FIG. 2 is a diagram schematically showing a hardware construction of the USB memory 1 a according to the first embodiment of the present invention.

Here, in the figure, since the reference characters the same as those which are already described indicate the same or approximately the same parts, their detailed descriptions will be omitted.

As shown in FIG. 2, the main body unit 10 a of the USB memory 1 a according to the first embodiment includes: a microcomputer 101; a buzzer circuit 108; a cap detection switch 109; a USB connector 17; a power circuit 112; a charge circuit 113; a battery 19; and a flash memory 110.

The cap detection switch 109, which is formed by, for example, a push switch, is pressed down under a state in which a cap 20 a is mounted to the USB connector 17 and is released when the cap 20 a is disengaged from the USB connector 17. This cap detection switch 109 functions as the switch (sensor) 16 shown in FIG. 1. In this instance, the cap detection switch 109 should by no means be limited to a push switch, and various changes or modifications thereof may be suggested without departing from the gist of the invention.

The power circuit 112 performs controlling of supply of electricity (bus power), supplied through the USB connector 17 and from the battery 19, to each part of the main body unit 10 a. Further, the power circuit 112 measures the remaining amount of battery 19, and also controls the charge circuit 113 to charge the battery 19. That is, this power circuit 112 functions as the battery measuring unit 18 shown in FIG. 1.

The charge circuit 113, which charges the battery 19 based on control performed by the power circuit 112, performs charging of the battery 19 with electricity supplied through the USB connector 17.

The flash (FLASH) memory 110, which is a semiconductor memory to which data deleting and data writing can be performed freely, is constructed in such a manner that the data stored therein does not vanish even after power is turned off and functions as the storage unit 11 shown in FIG. 1. In this flash memory 110, data reading, data writing, and data deleting (reading/writing/deleting) or the like is performed based on control of the flash (FLASH) memory interface 107 performed by the microcomputer 10.

In this instance, FIG. 2 shows an example in which more than one (three in the figure) flash memory 110 is provided. However, the present invention should by no means be limited to this, and flash memories 110 of the number not larger than two or not smaller than four can be provided.

The microcomputer 101, which performs various kinds of controlling in the USB memory 1 a, is constructed as an integrated circuit. As shown in FIG. 2, the microcomputer 101 includes: a processor 102; a RAM 103; a control soft ROM 104; a timer 105; a USB interface 106; and a flash (FLASH) memory interface 107.

The control soft ROM 104 stores various types of programs for realizing a function as the microcomputer 101.

The processor 102 executes such programs stored in the control soft ROM 104, thereby performing various kinds of controlling for realizing a function as the microcomputer 101.

The RAM 103 temporarily stores therein data and programs which are used at the time the processor 102 executes the programs.

The timer 105, which measures varying time durations, is formed as, for example, a counter, and it functions as the first timer 13 and the second timer 14 shown in FIG. 1.

The USB interface 106 controls various kinds of controlling for communicating with the PC 30 a through the USB connector 17 and the USB port 31. Further, the USB interface 106 detects that the USB memory 1 a is connected to the USB port 31 of the PC 30 a through the USB connector 17, and it functions as the connection detector 12 shown in FIG. 12.

The flash memory interface 107 performs controlling of data reading, data writing, data deleting (reading/writing/deleting) or the like in the flash memory 110.

The buzzer circuit 108, which outputs an alarming sound at a predetermined frequency in accordance with control by the microcomputer 101, functions as the alerting unit 15 shown in FIG. 1. This buzzer circuit 108 can be realized by using various types of already known circuits.

Here, this buzzer circuit 108 may automatically stop the alarming sound, for example, after outputting it for a predetermined time duration having been set beforehand, and also may stop the outputting of the alarming sound at the time any incoming input is performed. Various changes or modifications may be suggested without departing from the gist of the invention.

In this instance, such incoming inputs can be input operations of some kind by a user or the like, and includes inputting of a signal which is output in response to, for example, detection that the cap 20 a is engaged with the USB connector 17.

Further, the USB memory 1 a has a power switch for controlling ON/OFF (power on/power off) of electricity supply from the battery 19 to each part of the main body unit 10 a. In this instance, according to the present embodiment, it is preferable that the function as the power switch is provided for, for example, the switch 16 (cap detection switch 109) and then power is turned on by means of detecting that the cap 20 a is disengaged from the USB connector 17.

Still further, instead of making the switch 16 (cap detection switch 109) function as a power switch, another separate power switch can be provided.

FIG. 3 is a diagram schematically showing a hardware construction of a PC 30 a to which the USB memory 1 a is connected according to the first embodiment of the present invention.

As shown in FIG. 3, the PC (information processing apparatus) 30 a includes: a CPU 301; a ROM 302; a RAM 303; a display 304; an HDD 305; a keyboard 306; a mouse 307; a USB controller 308; and a USB port (USB connector, connection unit) 31.

The CPU (Central Processing Unit) 301, executes programs stored in the HDD 305 and the ROM 302, thereby performing various kinds of calculation operation processing, and performs various kinds of controlling in the PC 30 a.

The ROM (Read Only Memory) 302 stores programs and data used by the CPU 301; the RAM (Random Access Memory) 303 temporarily stores programs and data used by the CPU 301.

The display 304 is a display device which shows various types of information; the HDD (Hard Disk Drive) 305 is a storage device which holds and stores therein various kinds of programs and data; the keyboard 306 and the mouse 307 are input devices through which an operator performs various kinds of input operations and selection operations.

The USB port 31 is a connector (USB connector, female) formed in line with the Universal Serial Bus regulations, to which USB ports 31 the USB connectors of a variety of kinds of USB equipment formed in line with the USB regulations can be connected. The USB connector 17 of the USB memory 1 a can be inserted into/connected to the USB port 31 in such a manner that it can be attached and removed at will.

The USB controller 308 controls communication with the USB equipment (USB memory 1 a) connected through the USB port 31.

Referring to the flowchart (step A10 through A50), a description will be made hereinbelow of processing relating to uncapping of the cap 20 a in the USB memory 1 a according to the first embodiment of the present invention with the above described construction.

In the USB memory 1 a, when a user disengages the cap 20 a from the USB connector 17, the cap detection switch 109 (switch 16) detects this (detecting step), and the main body unit 10 a of the USB memory 1 a is turned on, and initialization processing for each unit in the main body unit 10 a is performed (step A10).

Further, when the cap detection switch 109 detects an uncapped state of the cap 20 a, in which the cap 20 a is uncapped from the USB connector 17 (see YES route of step A20), the timer 105 (first timer 13) measures (countdowns) a time duration that elapses under the uncapped state of the cap 20 a (first measuring step; step A30).

Then, the timer 105 evaluates if the first predetermined time duration having been set beforehand elapses, that is, whether or not the time is out (step A40). If the first predetermined time duration has not yet elapsed (see NO route of step A40), the processing returns to step A20. Contrarily, if the first predetermined time duration elapses (see YES route of step A40), the timer 105 outputs a first predetermined time duration detection signal to the buzzer circuit 108 (alerting unit 15), which then outputs a predetermined alarming sound, thereby alerting the user (first alerting step; step A50), and ends the processing.

Further, when it is detected by the cap detection switch 109 that the cap 20 a is engaged with the USB connector 17 (an engagement state) (see NO route of step A20), the processing ends.

Next, referring to the flowchart (step B10 through 870) shown in FIG. 5, a description will be made of the processing relating to connection of the USB memory 1 a with the PC 30 a according to the first embodiment of the present invention.

In the USB memory 1 a, when a user uncaps the cap 20 a from the USB connector 17, the cap detection switch 109 detects this, and the main body unit 10 a of the USB memory 1 a is turned on, and initialization processing for each unit in the main body unit 10 a is performed (step B10).

Then, when the USB interface 106 (connection detector 12) detects that the main body unit 10 a is connected (USB connection) to the USB port 31 of the PC 30 a through the USB connector 17 (see YES route of step B20), the timer 105 (second timer 14) measures (countdowns) a time duration that elapses under a state in which the USB connector 17 is connected to the PC 30 a (second measuring step; step B30).

The timer 105 (second timer 14) evaluates if the second predetermined time duration having been set beforehand elapses, that is, whether or not the time is out (step B40). If the second predetermined time duration has not yet elapsed (see NO route of step B40), an access request to the flash memory 110 (storage unit 11) such as data reading, data writing, and data deleting, are waited for (step B60).

If any access request is sent from the PC 30 a (see YES route of step B60), the flash memory interface 107 performs the processing of data reading or the like to the flash memory 110 in obedience to the request (step B70), and the processing returns to step B30.

Further, if the second predetermined time duration elapses (see YES route of step B40), the timer 105 outputs a second predetermined time duration detection signal to the buzzer circuit 108 (alerting unit 15). Upon reception of the second predetermined time duration detection signal, the timer 105 outputs a predetermined alarming sound to the buzzer circuit 108 (alerting unit 15), and the buzzer circuit 108, which received the second predetermined time duration detection signal, outputs a predetermined alarming sound, thereby alerting the user (second alerting step; step B50), and the processing shifts to step B60.

Still further, in a case where no access request from the PC 30 a is present (see NO route of step B60), the processing returns to step B30.

In this manner, with the USB memory 1 a according to the first embodiment of the present invention, since the alerting unit 15 gives an alert to the user of the SB memory 1 a upon elapse of the first predetermined time duration from uncapping of the cap 20 a from the USB connector 17, it is possible to make the user of the USB memory 1 a recognize that the USB memory 1 a is being in use. As a result, for example, it is possible to prevent the USB memory 1 a from being left in a state in which the USB memory 1 a is inserted to the PC 30 a, so that an occurrence of leaving the USB memory 1 a behind can be prevented.

Further, since the alerting unit 15 gives an alert to the user of the USB memory 1 a upon elapse of the second predetermined time duration under a state in which the USB memory 1 a is connected to the PC 30 a through the USB connector 17 and the USB port 31, it is possible to make the user of the USB memory 1 a recognize that the USB memory 1 a is being in use. As a result, it is possible to prevent the USB memory 1 a from being leaved in a state in which the USB memory 1 a is inserted to the PC 30 a, so that an occurrence of leaving the USB memory 1 a behind can be prevented.

Still further, since the alerting unit 15 gives an alert to the user of the USB memory 1 a also when it is detected that the remaining battery amount in the battery 19 is not larger than a predetermined amount, it is possible for the user to acknowledge that the remaining battery amount in the battery 19 is small, so that he/she can charge the USB memory 1 a. As a result, such a state can be prevented from occurring as that in which each of the units of the main body unit 10 a is incapable of executing the function thereof due to shortage of the remaining battery amount in the battery 19 of the USB memory 1 a. This improves the reliability of the USB memory 1 a.

Yet further, since the battery 19 automatically charges with USB bus power during the time in which the USB memory 1 a is being connected to the PC 30 a through the USB connector 17 and the USB port 31, it is possible to resolve the problem of the shortage of the remaining battery amount in the battery 19. This not only improves the reliability of the USB memory 1 a but also improve the convenience thereof.

(B) First Modified Example of First Embodiment

FIG. 6 is a diagram schematically showing a first modified example of the functional construction of the USB memory 1 b according to a first modified example of the first embodiment of the present invention.

Similar to the USB memory 1 a of the first embodiment, the USB memory (electronic apparatus) 1 b is connected to the PC 30 a (see FIG. 3) in a communicable manner therebetween by means of inserting/connecting the USB connector 17 to the USB port 31 of the PC 30 a. This PC 30 a accesses the storage unit 11 to perform data reading, data writing, and data deleting. As shown in FIG. 6, the USB memory 1 b includes: a main body unit 10 b having a USB connector (communication unit, connection terminal) 17 and a storage unit 11; and a cap (component) 20 b which is formed in such a manner that it is removable from the USB connector 17 (main body unit 10 b).

Further, as shown in FIG. 6, the USB memory 1 b has (i) the main body unit 10 b which includes: a storage unit 11; a connection detector 12; a second timer 14; an alerting unit 15-1; a USB connector 17; a battery measuring unit 18-1; and a battery 19-1, and (ii) a cap 20 b which includes a switch (sensor) 16; a first timer 13; an alerting unit 15-2; a battery 19-2; and a battery measuring unit 18-2.

Here, in the figure, since the reference characters the same as those which are already described indicate the same or approximately the same parts, their detailed descriptions will be omitted.

Further, the hardware construction of the main body unit 10 b is the same as that of the main body unit 10 a of the USB memory 1 a according to the first embodiment except that the cap detection switch 109 in FIG. 2 is provided for the cap 20 b. Still further, the cap 20 b includes: a timer 105; a power circuit 112; and a charge circuit 113; a battery 19; and a buzzer circuit 108 as well as the cap detection switch 109 shown in FIG. 2.

The alerting units 15-1 and 15-2, each of which has the same or approximately the same construction as that of the alerting unit 15 in the USB memory 1 a according to the first embodiment, is realized by the buzzer circuit 108. Further, similar to the alerting unit 15 of USB memory 1 a according to the first embodiment, the alerting unit 15-1 provided for the main body unit 10 b gives an alert when it receives a second predetermined time duration detection signal from the second timer 14 or when it receives a remaining amount detection signal from the battery measuring unit 18-1.

On the other hand, similar to the alerting unit 15 of the USB memory 1 a according to the first embodiment, the alerting unit 15-2 provided for the cap 20 b gives an alert when it receives a first predetermined time duration detection signal from the first timer 13.

The battery measuring units 18-1 and 18-2, each of which has the same or approximately the same construction as that of the battery measuring unit 18 in the USB memory 1 a according to the first embodiment, is realized by the power circuit 112. The battery measuring unit 18-1 measures the remaining battery amount of the battery 19-1. When detecting that the remaining battery amount is not larger than a predetermined amount, the battery measuring unit 18 outputs a remaining amount detection signal to the alerting unit 15-1. Further, the battery measuring unit 18-2 measures the remaining amount of battery of the battery 19. When detecting that the remaining battery amount is not larger than a predetermined amount, the battery measuring unit 18-2 outputs a remaining amount detection signal.

The batteries 19-1 and 19-2, each of which has the same or approximately the same construction as that of the battery 19 in the USB memory 1 a according to the first embodiment, supplies electricity to each of the units provided for the main body unit 10 b. The battery 19-2 supplies electricity to each of the units provided for the cap 20 b.

Further, in the USB memory 1 b according to the first modified example, the engagement opening 201 to the USB connector 17 is provided with a battery 19-2 and a power circuit 112 in the cap 20 b and the electrode 191 electrically coupled to the charge circuit 113. The power circuit 112, the charge circuit 113, and the battery 19-1 are coupled to the power circuit 112, the charge circuit 113, and the battery 19-2 provided for the cap 20 b through the electrode 191 by means of mounting the cap 20 b to the USB connector 17 of the main body unit 10 b.

That is, the USB memory 1 b according to the first modified example has a construction in which the cap 20 b and the battery 19-1 provided for the main body unit 10 b are electrically connectable under a state where the cap 20 b is engaged with the USB connector 17.

Then, when the power circuit 112 of the main body unit 10 b is coupled to the power circuit 112 and the charge circuit 113 which are provided for the cap 20 b through the electrode 191 by means of engaging the cap 20 b with the connection detector 12 b (USB connector 17), the battery 19-1 of the main body unit 10 b supplies electric current to the charge circuit 113 of the cap 20 b through the electrode 191. With such current supplied from the battery 19-1 of the main body unit 10 b, the charge circuit 113 charges the battery 19-2 provided for the cap.

That is, in the USB memory 1 b according to the first modified example, the battery 19-2 provided for the cap 20 b charges with electricity supplied from the battery 19-1 provided for the main body unit 10 b under a state where the cap 20 b is being engaged with the USB connector 17.

In the above described USB memory 1 b according to the first modified example of the first embodiment, the cap 20 b is uncapped from the USB connector 17 of the main body unit 10 b, and the USB connector 17 is inserted/connected to the USB port 31, thereby realizing data reading, data writing, data deleting or the like between the storage unit 11 and the PC 30 a.

In this instance, at that time, the battery 19-1 of the main body unit 10 b charges with electricity supplied by USB bus power through the USB connector 17.

Further, when the switch (sensor) 16 of the cap 20 b detects that the cap 20 b is disengaged from the USB connector 17 (falls in an disengaging state thereof) (detecting step), a signal (discharging state detection signal) is output to the first timer 13, which signal informs the first timer 13 as such.

After that, upon reception of the discharging state detection signal from the switch 16, the first timer 13 starts measuring (countdown) (first measuring step). Upon elapse of a predetermined time duration (first predetermined time duration) having been set beforehand, the first timer 13 outputs a signal (first predetermined time duration detection signal) to the alerting unit 15-2, which signal informs the alerting unit 15-2 as such. At that time, the alerting unit 15-2 which received the predetermined detection signal performs alerting with an alarming sound at a predetermined frequency (first alerting step).

Further, the battery measuring unit 18-2 measures the remaining amount of battery (remaining battery amount) of the battery 19-2. When detecting that the remaining battery amount is not larger than a predetermined amount, the battery measuring unit 18-2 outputs to the alerting unit 15-2 a remaining amount detection signal, and the alerting unit 15-2 gives an alert informing that the remaining battery amount is small.

On the other hand, in the main body unit 10 b, when detecting that the main body unit 10 b is connected to the PC 30 a through the USB connector 17, the connection detector 12 outputs to the second timer 14 a signal (connection detection signal) informing as such.

Upon reception of the connection detection signal from the connection detector 12, the second timer 14 starts measuring (countdown) (first measuring step). Upon elapse of a predetermined time duration (first predetermined time duration) having been set beforehand, the second timer 14 outputs a signal (second predetermined time duration detection signal) to the alerting unit 15-1, which signal informs the alerting unit 15-2 as such. At that time, upon reception of the second predetermined time duration detection signal, the alerting unit 15-1 gives an alert by means of generating an alarming sound at a predetermined frequency (second alerting step).

Further, the battery measuring unit 18-1 measures the remaining amount of battery (remaining battery amount) of the battery 19-1. When detecting that the remaining battery amount is not larger than a predetermined amount, the battery measuring unit 18-1 outputs to the alerting unit 15-1 a remaining amount detection signal, and the alerting unit 15-1 gives an alert informing that the remaining battery amount is small.

When a user engages the cap 20 b to the USB connector 17 of the main body unit 10 b, the battery 19-2 provided for the cap 20 b charges with electricity supplied from the battery 19-1 of the main body unit 10 b.

In this manner, with the USB memory 1 b according to the first modified example of the first embodiment of the present invention, the effects and benefits similar to those of the above described first embodiment are realized. In addition, since the battery 19-2 provided for the cap 20 b charges with electricity supplied from the battery 19-1 provided for the cap 20 b under a state where the cap 20 b is engaged with the USB connector 17, it is possible to charge also the battery 19-2 provided for the cap 20 b, so that improved convenience is realized.

(C) Second Modified Example of First Embodiment

FIG. 7 is a diagram schematically showing a second modified example of the functional construction of the USB memory 1 c according to a second modified example of the first embodiment of the present invention.

Similar to the USB memory 1 a of the first embodiment, the USB memory (electronic apparatus) 1 c is connected to the USB port of the PC 30 a (see FIG. 3) in a communicable manner therebetween by means of inserting/connecting the USB connector 17 to the PC 30 a. This PC 30 a accesses the storage unit 11 to perform data reading, data writing, and data deleting. As shown in FIG. 7, the USB memory 1 b includes: a main body unit 10 c which has the similar construction to that of the main body unit 10 a of the USB memory 1 a according to the first embodiment; and a cap (component) 20 c which has the similar construction to that of the cap 20 b according to the first modified example of the first embodiment, and is formed in such a manner that it is removable from the USB connector 17.

Here, in the figure, since the reference characters the same as those which are already described indicate the same or approximately the same parts, their detailed descriptions will be omitted.

The switches 16-1 and 16-2, each of which detects an uncapped state of the cap 20 c from the USB connector 17, have the same or the approximately the construction as that of the switch 16 according to the first embodiment, and is realized by the cap detection switch 109.

The first timer 13-1 measures a time duration that elapses under a state in which the cap 20 c is uncapped, from when the switch 16-1 detects that the cap 20 c is disengaged. The first timer 13-2 measures a time duration that elapses under a state in which the cap 20 c is uncapped, from when the switch 16-2 detects that the cap 20 c is uncapped.

Further, these first timers 13-1 and 13-2 each have the same or approximately the same construction as that of the first timer 13 according to the first embodiment.

In the USB memory 1 c according to the second modified example of the first embodiment, the cap 20 c is uncapped from the USB connector 17 of the main body unit 10 c, and the USB connector 17 is inserted/connected to the USB port 31, thereby realizing data reading, data writing, data deleting or the like between the storage unit 11 and the PC 30 a.

In this instance, at that time, the battery 19-1 of the main body unit 10 c charges with electricity supplied by USB bus power through the USB connector 17.

Further, when the switch (sensor) 16-2 of the cap 20 c detects that the cap 20 c is uncapped from the USB connector 17 (falls in an uncapped state thereof) (detecting step), a signal (discharging state detection signal) is output to the first timer 13-2, which signal informs the first timer 13 as such.

After that, upon reception of the discharging state detection signal from the switch 16-2, the first timer 13-2 starts measuring (countdown) (first measuring step). Upon elapse of a predetermined time duration (first predetermined time duration) having been set beforehand, the first timer 13-2 outputs a signal (first predetermined time duration detection signal) to the alerting unit 15-2, which signal informs the alerting unit 15-2 as such. At that time, upon reception of the predetermined time duration detecting signal, the alerting unit 15-2 gives an alert by means of generating an alarming sound at a predetermined frequency (first alerting step).

Further, the battery measuring unit 18-2 measures the remaining amount of battery (remaining battery amount) of the battery 19-2. When detecting that the remaining battery amount is not larger than a predetermined amount, the battery measuring unit 18-2 outputs a remaining amount detection signal to the alerting unit 15-2, and the alerting unit 15-2 gives an alert informing that the remaining battery amount is small.

On the other hand, in the main body unit 10 c, also, when the switch (sensor) 16-1 detects that the cap 20 c is disengaged from the USB connector 17 (falls in an uncapped state) (detecting step), a signal (uncapped state detection signal) is output to the first timer 13-1 informing as such.

Upon reception of the uncapped state detection signal from the connection detector 12, the first timer 13-1 starts measuring (countdown) (first measuring step). Upon elapse of a predetermined time duration (first predetermined time duration) having been set beforehand, the first timer 13-1 outputs a signal (first predetermined time duration detection signal) to the alerting unit 15-1, which signal informs the alerting unit 15-1 as such. At that time, upon reception of the predetermined time duration detection signal, the alerting unit 15-1 gives an alert by means of generating an alarming sound at a predetermined frequency (first alerting step).

Further, upon detection that the main body unit 10 c is connected to the PC 30 a through the USB connector 17, the main body unit 10 c outputs a signal (connection detection signal) informing as such to the second timer 14. Then, upon elapse of a predetermined time (a second predetermined time duration) having been set beforehand, the second timer 14 outputs a signal (second predetermined time duration detection signal) informing as such to the alerting unit 15-1. At that time, upon reception of the predetermined time duration detecting signal, the alerting unit 15-1 gives an alert by means of generating an alarming sound at a predetermined frequency (second alerting step).

Further, the battery measuring unit 18-1 measures the remaining amount of battery (remaining battery amount) of the battery 19-1. When detecting that the remaining battery amount is not larger than a predetermined amount, the battery measuring unit 18-1 outputs a remaining amount detection signal to the alerting unit 15-1, and the alerting unit 15-1 gives an alert informing that the remaining battery amount is small.

When a user engages the cap 20 c to the USB connector 17 of the main body unit 10 c, the battery 19-2 provided for the cap 20 c charges with electricity supplied from the battery 19-1 of the main body unit 10 c.

In this manner, with the USB memory 1 c according to the second modified example of the first embodiment of the present invention, the effects and benefits similar to those of the above described first embodiment and the first modified example of the first embodiment are realized.

In addition, since the alerting unit 15-2 is provided also for the cap 20 c, which alerting unit 15-2 also gives an alert, it is possible for a user to receive such an alert more assuredly, so that the reliability can be improved.

(D) Second Embodiment

FIG. 8 is a diagram schematically showing a functional construction of a USB (Universal Serial Bus) memory according to a second embodiment of the present invention.

Similar to the USB memory 1 a of the first embodiment, the USB memory (electronic apparatus) 1 d is connected to the USB port 31 of the PC 30 a (see FIG. 3) in a communicable manner therebetween by means of inserting/connecting the USB connector (communication unit, connection terminal) 17 to the PC 30 a. This PC 30 a accesses the storage unit 11 to perform data reading, data writing, and data deleting. As shown in FIG. 8, the USB memory 1 d has the same construction as that of the USB memory 1 a of the first embodiment, including: a main body unit 10 d having a USB connector 17 and a storage unit 11; and a cap (component) 20 d which is formed in such a manner that it is removable from the USB connector 17.

As shown in FIG. 8, the USB memory 1 d according to the second embodiment has a deleting unit 21 in place of the alerting unit 15 and the battery measuring unit 18 of the USB memory 1 a according to the first embodiment. The other parts of the USB memory 1 d are the same as those of the USB memory 1 a according to the first embodiment.

The deleting unit 21 deletes (removes) data stored in the storage unit 11. Upon detection of elapse of a third predetermined time duration (first predetermined time duration) by the first timer 13, the deleting unit 21 deletes data stored in the storage unit 11.

Further, the deleting unit 21 deletes (removes) data stored in the storage unit 11 also when the second timer 14 detects that a fourth predetermined time duration (the second predetermined time duration) elapses.

In this instance, the deleting unit 21 is realized by, for example, the flash memory interface 107 shown in FIG. 2. Further, the deleting unit 21 may delete all the data stored in the flash memory 110 (storage unit 11), or may delete only specific data. As to making the deleting unit 21 delete specific data, it can be realized by means of giving settings (flags), which indicate whether subject data is to be deleted or not to be deleted, to the data, or by means of giving setting which prohibits data, whose deletion is not expected, from being deleted by use of a data protection function that an OS (Operating System) or the like of a computer has.

The battery 19 automatically charges with electricity supplied from the PC 30 a through the USB connector 17 and/or the USB port 31 under a state in which the USB memory 1 d (main body unit 10 d) is being connected to the PC 30 a.

Hereinafter, referring to the flowchart (step C10 through C50) in FIG. 9, a description will be made of the processing relating to uncapping of the cap 20 d in the USB memory 1 d according to the second embodiment of the present invention with the construction described above.

In the USB memory 1 d, when a user uncaps the cap 20 d from the USB connector 17, the cap detection switch 109 (switch 16) detects this (detecting step), and the main body unit 10 d of the USB memory 1 d is turned on, and initialization processing to each of the units in the main body unit 10 d is performed (step C10).

Then, when the cap detection switch 109 detects the state in which the cap 20 d is uncapped (see YES route of step C20), the timer 105 measures (countdowns) a time duration that elapses at the state in which the cap 20 d is being uncapped (first measuring step; step C30).

After that, the timer 105 (first timer 13) evaluates whether or not a third predetermined time duration having been set beforehand elapses, that is, if the time is out (step C40). If the third predetermined time duration has not yet elapsed (see NO route of step C40), the processing returns back to step C20. Contrarily, if the third predetermined time duration elapses (see YES route of step C40), the timer 105 outputs a third predetermined time detection signal to the flash memory interface 107 (deleting unit 21). The flash memory interface 107 deletes the data stored in the flash memory 110 (storage unit 11) (first deleting step; step C50), and then ends the processing.

Further, when the cap detection switch 109 detects that the cap 20 disengaged with the USB connector 17 (engaged stated) (see NO route of step C20), the processing ends.

Next, referring to the flowchart (step D10 through D70) in FIG. 10, a description will be made of the processing relating to connection of the USB memory 1 d to the PC 30 a according to the second embodiment of the present invention.

In the USB memory 1 d, when a user uncaps the cap 20 d from the USB connector 17, the cap detection switch 109 detects this, and the main body unit 10 d of the USB memory 1 d is turned on, and initialization processing to each of the units in the main body unit 10 d is performed (step D10).

Then, when the USB interface 106 (connection detector 12) detects that the main body unit 10 d is connected (USB connection) to the USB port 31 of the PC 30 a (see YES route of step D20), the timer 105 (second timer 14) measures (countdowns) a time duration that elapses at the state in which the USB connector 17 is being connected to the PC 30 a (second measuring step; step D30).

The timer 105 (second timer 14) evaluates whether or not the time is out, that is, whether or not a fourth predetermined time duration having been set beforehand elapses, that is, if the time is out (step D40). If the fourth predetermined time duration has not yet elapsed (see NO route of step D40) an access request to the flash memory 110 (storage unit 11) such as data reading, data writing, and data deleting (step D40), is waited for.

When an access request is sent from the access request from the PC 30 a (see YES route of step D60), the flash memory interface 107 performs such processing such as data reading and data writing (step D70), and the processing returns back to step D30.

Contrarily, if the fourth predetermined time duration elapses (see YES route of step D40), the timer 105 outputs a fourth predetermined time detection signal to the flash memory interface 107 (deleting unit 21). The flash memory interface 107 deletes the data stored in the flash memory 110 (storage unit 11) (second deleting step; step D50), and then the processing shifts to step D60.

Still further, in a case of absence of any access request from the PC 30 a (see NO route of step D60), the processing returns back to step D30.

In this manner, with the USB memory 1 d according to the second embodiment of the present invention, upon elapse of the third predetermined time duration from when the cap 20 d uncapped from the USB connector 17, the deleting unit 21 deletes the data stored in the storage unit 11. As a result, even when, for example, the USB memory 1 d is leaved to be inserted to the PC 30 a, a third person who obtains the USB memory 1 d is incapable of using data stored in the storage unit 11, so that it is possible to improve the confidentiality of data, thereby preventing the leakage of confidential information.

Further, since the deleting unit 21 deletes the data stored in the storage unit 11 upon elapse of the fourth predetermined time duration from when the USB memory 1 d is connected to the PC 30 a through the USB connector 17 and the USB port 31. This also makes it possible to improve data confidentiality, thereby preventing the leakage of confidential information.

Still further, since the battery 19 automatically charges with USB bus power while the USB memory 1 d is being connected to the PC 30 a through the USB connector 17 and the USB port 31, it is possible to resolve the problem of the shortage of the remaining battery amount of the battery 19, so that high convenience is realized.

(E) Third Embodiment

FIG. 11 is a diagram schematically showing functional constructions of a PC (information processing apparatus, computer) 30 e and a USB (Universal Serial Bus) memory 1 e according to a third embodiment of the present invention.

Here, in the figure, since the reference characters the same as those which are already described indicate the same or approximately the same parts, their detailed descriptions will be omitted.

The PC 30 e according to the third embodiment includes a USB port [USB connector (female); connector] 31 to which the USB memory (electronic apparatus) 1 e is connected in a communicable manner therebetween. The PC 30 e is connected to the USB memory 1 e in a communicable manner therebetween by means of inserting/connecting the USB connector (communication unit, connection terminal) 17 of the USB memory 1 e to this USB port 31. From this PC 30 e, data reading, data writing, and data deleting are performed to the storage unit 11 of the USB memory 1 e.

Further, similar to the PC 30 a according to the first embodiment, the PC 30 e according to the third embodiment has a hardware construction shown in FIG. 3, and thus, its detailed description will be omitted.

As shown in FIG. 11, the USB memory 1 e includes: a main body unit 10 e having a USB connector (communication unit, connection terminal) 17 and a storage unit 11; and a cap (component; not illustrated) which has the similar construction to that of the cap 20 a in the first embodiment and is formed in such a manner that it is removable from the USB connector 17.

As shown in FIG. 11, the PC 30 e includes: a USB port 31; a connection detector 45; an alert controller 33; a unused state detector 34; a user detector 35; a timer 36; an alerting unit 37; a user confirming unit 38; a user information obtaining unit 39; and a USB memory confirming unit 40.

The connection detector 45 detects that the USB memory 1 e is connected to the USB port 31. For example, similar to the connection detector 12 of the USB memory 1 a, the connection detector 45 is realized by a USB interface or the like. In this instance, detection of connection to the USB memory 1 e performed by the connection detector 45 can also be realized by means of using a variety of kinds of already known methods.

Further, when detecting that the USB memory 1 e is connected to the PC 30 e, the connection detector 45 outputs a signal (connection detection signal) which informs the timer 36 as such.

The timer 36, which measures a time duration that elapses under a connection-established state, in which the USB memory 1 e is connected to the PC 30 e, from when the connection detector 45 detects that the USB memory 1 e is connected to the PC 30 e, is realized by the timer 105 (see FIG. 2) which is constructed as, for example, a counter, like the second timer 14 of the USB memory 1 a according to the first embodiment.

Upon elapse of a predetermined time duration (second predetermined time duration) having been set beforehand, the timer 36 outputs a signal (second predetermined time duration detection signal) notifying the alerting unit 37 of the elapse of the predetermined time duration.

The user confirming unit 38 confirms that a person (user) who is using/operating the PC 30 e is a specific authorized user of the PC 30 e. In the third embodiment, on the basis of the information (user information) obtained by the user information obtaining unit 39, the user confirming unit 38 confirms that the user of the PC 30 e is a specific authorized user of the PC 30 e.

In this instance, such a specific authorized user of the PC 30 e means a person who has any validity in use of the PC 30 e, such as the owner of the PC 30 e and people who are given a permission to use the PC 30 e from the owner, and information relating to such specific authorized users (specific authorized user information; not illustrated) is registered beforehand in the HDD 305 or the like of the user information obtaining unit 30 e of the PC 30 e. That is, it can be said that a person whose specific authorized user information is registered beforehand is a specific authorized user.

The user information obtaining unit 39 for obtaining information relating to a user of the PC 30 e, obtains information (for example, information relating to a password, a fingerprint picture image, a picture image of a user's face, a smart card, and a FeLica card) for use in confirming that the user of the PC 30 e is an identified authorized user.

For example, when the user confirming unit 38 performs user confirmation by use of password authentication, an input apparatus such as the keyboard 306 used for inputting a password therethrough functions as a user information obtaining unit 39. In this case, the user confirming unit 38 makes a user input a password through the keyboard 306 or the like, and then admits the user of the PC 30 e is a specific authorized user when the input password matches any of the registered passwords (specific authorized user information).

Further, when the user confirming unit 38 performs face authentication, a camera used in inputting a picture image of a user's face functions as the user information obtaining unit 39. In this case, the user confirming unit 38 takes a picture of a user's face or the like, and compares the obtained picture with data for authentication (image data or characteristic feature data, which has been registered beforehand; specific authorized user information) having been registered beforehand.

Still Further, when the user confirming unit 38 performs fingerprint authentication, a fingerprint sensor used in inputting of a fingerprint functions as the user information obtaining unit 39. In this case, the user confirming unit 38 makes a user input his/her fingerprint, and compares the input fingerprint data with registered fingerprint data having been registered beforehand (specific authorized user information).

Yet further, when a card reader reads information of a smart card or a FeLica card carried by a user and user authentication is performed by comparing card registration information (specific authorized user information) having been registered beforehand, the card reader for use in reading the information contained in the card functions as the user information obtaining unit 39.

In this instance, a confirmation method used by the user confirming unit 38 for evaluating whether or not a user is a specific authorized user, should by no means be limited to the above described method, and various kinds of already known authentication can be employed. Equipment used for obtaining necessary information at such authentication is equivalent to the user information obtaining unit 39.

Then, when deciding that the user of the PC 30 e is a specific authorized user of the PC 30 e, the user confirming unit 38 outputs a signal (specific authorized user detection signal) indicating as such to the alert controller 33, which will be described later.

The USB memory confirming unit 40 evaluates whether or not the USB memory 1 e connected to the PC 30 e is related to a specific authorized user.

Here, the expression of “the USB memory 1 e related to an authorized user” means that the USB memory 1 e is the one which is used by a specific authorized user related to the PC 30 e.

Confirmation performed by the USB memory confirming unit 40, that the USB memory 1 e relates to a specific authorized user is executed in the following manner. First of all, the HDD 305 or the like of the PC 30 e stores therein management information, indicating that a USB memory 1 e is owned by a specific authorized user, as a management list, and the storage unit 11 of the USB memory 1 e stores therein the same management information in the storage unit 11 of the USB memory 1 e.

Then, when the USB memory 1 e is engaged with the USB port 31 of the PC 30 e, the USB memory confirming unit 40 reads management information stored in the storage unit 11 in the USB memory 1 e, and confirms that the USB memory 1 e is related to a specific authorized user by means of collating the read out management information with the management information of the management list registered in the PC 30 e. That is, it can be said that the USB memory 1 e whose management information has been registered in the PC 30 e beforehand is the USB memory 1 e relating to a specific authorized user.

Further, when confirming that the USB memory 1 e connected to the USB memory 1 e relates to a specific authorized user, the USB memory confirming unit 40 outputs a signal (USB memory confirmation signal) indicating as such to the alert controller 33.

The user detector 35 detects the presence of a user in the PC 30 e, and is capable of detecting the presence of a user who operates the PC 30 e by means of, for example, using various types of sensors.

Further, when detecting the presence of a user who operates the PC 30 e, the user detector 35 outputs a signal (user detection signal) indicating as such to the unused state detector 34.

The unused state detector 34 detects the transition of the PC 30 e into an unused state thereof by the user. When detecting that the PC 30 e falls in a state with no user, the unused state detector 34 outputs a signal (unused state detection signal) indicating as such to the alert controller 33.

The unused state detector 34 detects the transition of the PC 30 e to an unused state thereof when at least any one of the following states is detected: (1) a state in which power-off of the PC 30 e is detected; (2) a state in which shift of the PC 30 e into a power-saving operation mode is detected; (3) a state in which the presence of a user which was detected by the user detector 35 is not detected anymore.

In this instance, detection of power-off in the PC 30 e and detection of the PC's shift to a power-saving operation mode can be realized by using various types of already known methods.

Further, the method in use of the unused state detector 34 for detecting transition of the PC 30 e to the unused state thereof should by no means be limited to the above-described method, and a variety of kinds of modifications can be applied.

For example, the PC 30 e may decide that the absence of a user when an input operation through the keyboard 306 and the mouse 307 is not consecutively performed. In this case, the CPU 301 of the PC 30 e functions as the user detector 35.

The alerting unit 37, which alerts a user of the PC 30 e, has the same or approximately the same construction as that of the alerting unit 15 according to the first embodiment. The alerting unit 37 is realized by, for example, a buzzer circuit.

This alerting unit 37 gives an alert when the timer 36 detects that a predetermined time duration (second predetermined time duration) is elapsed. Concretely, the alerting unit 37 gives an alert upon reception of the second predetermined time duration.

In addition, the alerting unit 37 gives an alert when the unused state detector 34 detects transition of the PC 30 e to an unused state thereof. Concretely, the alerting unit 37 gives an alert upon reception of an unused state detection signal from the unused state detector 34.

The alert controller 33 restrains an alert given by the alerting unit 37. In a case where a user of the PC 30 e is a specific authorized user relating to the USB memory 1 e, the alert controller 33 restrains the alerting unit 37 from giving an alert. More specifically, upon reception of a specific authorized user detection signal from the user confirming unit 38, the alert controller 33 restrains the alerting unit 37 from giving an alert even when the timer 36 detects that a predetermined time duration elapses.

Further, when the USB memory confirming unit 40 confirms that the USB memory confirming unit 40 confirms 1 e connected to the PC 30 e is the one which relates to a specific authorized user, that is, when the alert controller 33 receives a USB memory confirming signal from the USB memory confirming unit 40, the alert controller 33 restrains the alerting unit 37 from giving an alert even when the timer 36 detects that a predetermined time duration elapses.

In the PC 30 e with the above described construction according to the third embodiment of the present invention, the storage unit 11 of the USB memory 1 e of the USB memory 1 e sets (stores) therein management information, and the management information is registered in a management list of the PC 30 e.

Then, when the USB memory 1 e is inserted into the USB port 31 of the PC 30 e, the USB memory confirming unit 40 of the PC 30 e accesses the storage unit 11 of the USB memory 1 e through the USB port 31 and the USB connector 17 to obtain the management information therefrom, and then compares the obtained management information with a management list stored in the HDD 305 or the like, thereby evaluating whether or not the USB memory 1 e connected to the PC 30 e is the one which relates to a specific authorized user.

The USB memory confirming unit 40 outputs a USB memory confirmation signal to the alert controller 33 when the USB memory 1 e connected to the PC 30 e is the one which relates to a specific authorized user.

Further, the user confirming unit 38 confirms that a user is a specific authorized user relating to the PC 30 e based on user information obtained by the user information obtaining unit 39, When deciding that a person (user) who is using/operating the PC 30 e is a specific authorized user relating to the PC 30 e, the user confirming unit outputs a specific authorized user detection signal to the alert controller 33.

When detecting that the USB memory 1 e is connected to the USB port 31 (connection detecting step), the connection detector 45 outputs a signal (connection detection signal) informing as such to the timer 36, and the timer 36 measures a time duration that elapses under a connection-established state, in which the USB memory 1 e is connected to the PC 30 e, from when the connection detector 45 detects that the USB memory 1 e is connected to the PC 30 e (measuring step). Then, upon elapse of a predetermined time duration (a second predetermined time duration), which has been set beforehand, the timer 36 outputs a second predetermined time duration detection signal to the alerting unit 37.

Further, when detecting that the PC 30 e falls in an unused state thereof based on the information from the user detector 35 or the like (unused state detecting step) the unused state detector 34 outputs an unused state detection signal to the alert controller 33.

After receiving the second predetermined time duration detection signal or the unused state detection signal, the alerting unit 37 gives an alert (alerting step), whereas the alert controller 33 performs control in such a manner that an alert given by the alerting unit 37 is restrained (alert controlling step) when this alert controller 33 receives a USB memory confirmation signal or a specific authorized user detection signal.

In such a manner, with the PC 30 e according to the third embodiment of the present invention, the alerting unit 37 gives an alert when the second predetermined time duration elapses from when the USB memory 1 e is connected to the PC 30 e through the USB connector 17 and the USB port 31, or when the PC 30 e falls in an unused state thereof. This arrangement makes it possible for a user of the USB memory 1 e to recognize the USB memory 1 e is being used, and also makes it possible to prevent the USB memory 1 e from being left in a state in which the USB memory 1 a is inserted to the PC 30 e, so that an occurrence of leaving the USB memory 1 e behind can be prevented.

In a case where the user confirming unit 38 decides that a user of the PC 30 e is a specific authorized user relating to the USB memory 1 e, and/or in a case where the USB memory confirming unit 40 decides that the USB memory 1 e connected to the PC 30 e is the one relating to a specific authorized user, the alert controller 33 restrains the alerting unit 37 from giving an alert. As a result, the alerting unit 37 never gives an alert even when the second predetermined time duration elapses from when the USB memory 1 e is connected to the PC 30 e through the USB connector 17 and the USB port 31, and even when the PC 30 e falls in an unused state thereof, so that it can avoid a user from being annoyed by an alert, and thus, the convenience is resultantly improved.

Further, since the user information obtaining unit 39 obtains user information, it is possible for the user confirming unit 38 to confirm that a user is a specific authorized user relating to the PC 30 e with ease and reliability.

(F) Fourth Embodiment

FIG. 12 is a diagram schematically showing a functional construction of a USB (Universal Serial Bus) memory 1 f according to a fourth embodiment of the present invention.

Similar to the USB memory 1 a according to the first embodiment, the USB memory (electronic apparatus) 1 f according to the fourth embodiment is inserted/connected to a USB port 31 of a PC 30 a, the USB memory 1 f being thereby connected to the PC 30 a in a communicable manner therebetween, and data writing, data reading, and data deleting in the storage unit 11 are performed from the PC 30 a. As shown in FIG. 12, the USB memory 1 f includes: the main body unit 10 f having the USB connector (communication unit, connection terminal) 17 and the storage unit 11; and a cap 20 f having the similar construction to that of the cap 20 a of the USB memory 1 a according to the first embodiment, which cap 20 f is constructed in such a manner that it can be uncapped from the USB connector 17.

As shown in FIG. 12, the USB memory (electronic apparatus) 1 f according to the forth embodiment has a construction of the USB memory 1 a according to the first embodiment with addition of the alert controller 33, the user confirming unit 38, and the USB memory confirming unit 40 thereto, and the other parts of the USB memory 1 f have the constructions similar to those of the USB memory 1 a according to the first embodiment.

Here, in the figure, since the reference characters the same as those which are already described indicate the same or approximately the same parts, their detailed descriptions will be omitted.

Similar to the above described USB memory 1 a according to the first embodiment, in the USB memory 1 f according to the fourth embodiment, the alerting unit 15 gives an alert to a user of the USB memory 1 f when the first predetermined time duration is elapsed from when the cap 20 f is uncapped from the USB connector 17 and also when the second predetermined time duration elapses from when the USB memory 1 f is connected to the PC 30 a through the USB connector 17 and the USB port 31.

Further, similar to the PC 30 e of the third embodiment, in the USB memory 1 f according to the fourth embodiment, the user confirming unit 38 confirms that a user of the PC 30 a is a specific authorized user related to the PC 30 a, and the alert controller 33 restrains the alerting unit 35 from giving an alert in a case where the USB memory confirming unit 40 decides that the USB memory 1 f connected to the PC 30 a is the one which relates to a specific authorized user.

With this arrangement, as described above, the alerting unit 15 never gives an alert even when the second predetermined time duration elapses form when the USB memory 1 f is connected to the PC 30 a through the USB connector 17 and the USB port 31, and even when the PC 30 a falls in an unused state thereof, so that it can be prevented a user from being annoyed by an alert, and thus, the convenience is resultantly improved.

In this manner, with the USB memory 1 f according to the fourth embodiment of the present invention, the effects and benefits realized by the above described first embodiment and third embodiments are realized.

(G) Fifth Embodiment

FIG. 13 is a diagram schematically showing a functional construction of a USB (Universal Serial Bus) memory 1 g and a PC (information processing apparatus, computer) 30 g which is used with the USB memory 1 g coupled thereto according to a fifth embodiment of the present invention.

Similar to the USB memory 1 a according to the first embodiment, in the USB memory (electronic apparatus) 1 g according to the fifth embodiment, the USB connector 17 of the USB memory 1 g is inserted/connected to a USB port 31 of the PC 30 g, the USB memory 1 g being thereby connected to the PC 30 g in a communicable manner therebetween, and data writing, data reading, and data deleting in the storage unit 11 of the USB memory 1 g are performed from the PC 30 g.

As shown in FIG. 13, the PC 30 g according to the fifth embodiment includes: a USB port [USB connector (female); connection unit] 31; and a storage unit 32.

In this instance, similar to the PC 30 a according to the first embodiment, since the PC 30 g has a hardware construction as shown in FIG. 3, its detailed description will be omitted here.

The storage unit 32, which stores various kinds of data, stores the data stored in the storage unit 11 in obedience to control performed by a copy controlling unit 22, which will be described later. This storage unit 32 is formed by a storage device such as the HDD 305 and the RAM 303 shown in FIG. 3.

As shown in FIG. 13, the main body unit 10 g of the USB memory 1 g has the construction of the main body unit 10 d of the USB memory 1 d according to the second embodiment shown in FIG. 8 with a copy controlling unit 22, a copy inhibitor 41, an access inhibitor 42, an unused state detector 34, and a user detector 35, added thereto.

As shown in FIG. 13, the USB memory 1 g includes: a main body unit 10 g having a USB connector (communication unit, connection terminal) 17 and a storage unit 11; and a cap (component; not illustrated) which has the construction similar to the cap 20 a of the USB memory 1 a according to the first embodiment and is formed in such a manner that it is removable from the USB connector 17.

Here, in the figure, since the reference characters the same as those which are already described indicate the same or approximately the same parts, their detailed descriptions will be omitted.

The first timer 13 measures a time duration that elapses under a state in which the cap is uncapped, from when the switch 16 detects that the cap is uncapped. Upon detection that a fifth predetermined time duration (first predetermined time duration) having been set beforehand elapses under the uncapped state, the first timer 13 outputs a signal (fifth predetermined time duration detection signal) indicating as such to the copy controlling unit 22, which will be described later.

Further, when detecting a sixth predetermined time duration (second predetermined time duration) having been set beforehand elapses under the uncapped state, the first timer 13 outputs a signal (sixth predetermined time duration detection signal) indicating as such to the deleting unit 21.

In this instance, this fifth predetermined time duration is shorter than the sixth predetermined time duration, so that it is possible to back up the data stored in the storage unit 11 before the deleting unit 21 deletes the data.

Further, when detecting that a seventh predetermined time duration (fourth predetermined time duration) having been set beforehand elapses after the connection detector 12 detects that the USB connector 17 is connected to the PC 30 g, the second timer 14 outputs a signal (seventh predetermined time duration detection signal) indicating as such to the deleting unit 21.

When detecting that the PC 30 g falls in an unused state thereof based on information or the like from the user detector 35 or the like, the unused state detector 34 outputs an unused state detection signal to the deleting unit 21.

The copy controlling unit 22 performs controlling such that the data stored in the storage unit 11 of the USB memory 1 g is copied (backed up) in the storage unit 32 provided for the PC 30 g. Upon reception of the fifth predetermined time duration signal from the first timer 13, that is, when the first timer 13 detects that the fifth predetermined time duration elapses, the copy controlling unit 22 makes the data stored in the storage unit 11 of the USB memory 1 g to be copied in the storage unit 32 provided for the PC 30 g, thereby realizing backup of the data stored in the storage unit 11 of the USB memory 1 g in the storage unit 32.

When performing backup of the data stored in the storage unit 11 of the USB memory 1 g, this copy controlling unit 22 firstly notifies the PC 30 g of the amount of information stored in the storage unit 11 together with inquiring the PC 30 g of the transmission destination (storage destination; address) of the data to be backed up (reserving the transmission destination and the memory capacity). Then, when the PC 30 g sends (notifies) information about the transmission destination in response to the inquiry, the copy controlling unit 22 transmits the data to the thus notified transmission destination (storage unit 32) and makes the storage unit 32 store the transmitted information therein.

In this instance, in a case where the HDD 305 or the like of the PC 30 g does not have a capacity large enough to store the data for backup, the PC 30 g sends back information indicating the absence of the transmission destination to the USB memory 1 g (copy controlling unit 22). Here, it is preferable that the PC 30 g makes the display 304 thereof show a message indicating that the backup function is not available.

Further, the storage unit 11 of the USB memory 1 g is capable of setting/storing information (a backup transmission completion flag) indicating the completion of the backup to the storage unit 32 in association with information (for example, a file name, etc.) for identifying the data. Upon completion of backup of the data, the copy controlling unit 22 sets “1” to this backup transmission completion flag.

In this instance, this backup transmission flag may be set to each data item stored in the storage unit 11. Further, one backup transmission flag may be set to more than one item of data stored in the storage unit 11.

Still further, for example, when data stored in the storage unit 11 is deleted, the storage unit 11 is capable of setting/storing information (USB memory deletion completion flag), indicating that the data has been deleted by the deleting unit 21, in association with information (for example, filename) identifying the data in the storage unit 11. After deleting data stored in the storage unit 11, the deleting unit 21 sets “1” to this USB in memory deletion completion flag.

The copy inhibitor 41 prohibits the copy controlling unit 22 from copying data to the storage unit 32. For example, in a case where the PC 30 g is not the one which relates to a specific related person having a specific relationship with the USB memory 1 g, the copy inhibitor 41 prohibits the copy controlling unit 22 from copying data to the storage unit 32.

Further, evaluation as to whether or not the PC 30 g is the one which relates to a specific related person having a specific relationship with the USB memory 1 g, is performed in the following manner. For example, the USB memory 1 g registers therein a fingerprint or an ID password for authentication of the PC 30 g beforehand. The USB memory 1 g accesses the PC 30 g to obtain a fingerprint, an ID password or the like for authentication, and performs matching of the information thus obtained from the PC 30 g with the previously registered fingerprint, an ID password or the like.

Further, the copy inhibitor 41 prohibits the copy controlling unit 22 from copying data to the storage unit 32 also in a case where a user of the USB memory 1 g is not included in specific related people having specific relationships with the USB memory 1 g.

The “specific related people having a specific relationships with the USB memory 1 g” means such people who have any kind of validity in using the USB memory 1 g as a user of the USB memory 1 g, an owner of the PC 30 g, and a person who is permitted to use the USB memory 1 g.

Here, a variety of kinds of already known methods can be used for evaluating whether or not a user of the USB memory 1 g is one of such specific related people. For example, as shown in the above patent document 1, the storage unit 11 of the USB memory 1 g or the like registers therein fingerprints of the specific related people beforehand. When the USB memory 1 g is used by a user, fingerprint authentication of the user is performed, and matching of the thus obtained fingerprint data with registration fingerprint data is performed.

The deleting unit 21 deletes data stored in the storage unit 11. The deleting unit 21 deletes data stored in the storage unit 11 when it receives a sixth predetermined time duration detection signal from the first timer 13, that is, when elapse of the sixth predetermined time duration (second predetermined time duration) is detected, and when the deleting unit 21 receives a seventh predetermined time duration detection signal from the second timer 14.

In addition, in a case where data stored in the storage unit 11 is copied to the storage unit 32 of the PC 30 g, the deleting unit 21 deletes the data stored in the storage unit 11. Concretely, when “1” is set to the backup transmission flag set in the storage unit 11, the deleting unit 21 deletes the data in the storage unit 11, in which data, “1” is set to the backup transmission completion flag.

Further, when the deleting unit 21 deletes the data stored in the storage unit 11, the deleting unit 21 sets “1” to the USB memory deletion completion flag with respect to the data deleted from the storage unit 11 after completion of data deleting from the storage unit 11.

In this instance, the deleting unit 21 may delete data stored in the storage unit 11 only when the user of the PC 30 g is one of the specific related people having specific relationships with the PC 30 g.

The access inhibitor 42 inhibits the PC 30 g from accessing the storage unit 11. This access inhibitor 42 prohibits an access from the PC 30 g to the storage unit 11, when a user of the PC 30 g is not one of the specific related people having specific relationships with the PC 30 g.

Further, when a user of the USB memory 1 g is not one of the specific related people having specific relationships with the USB memory 1 g, the access inhibitor 42 inhibits the PC 30 g from accessing the storage unit 11.

In the USB memory 1 g according to the fifth embodiment of the present invention with the above construction, when the cap of the USB memory 1 g is uncapped from the USB connector 17 of the USB memory 1 g, the cap detection switch 109 detects that the cap has been uncapped (detecting step). Then, the main body unit 10 g of the USB memory 1 g is powered on, and initializing processing is performed in each unit of the main body unit 10 g.

Then, the first timer 13 measures a time duration that elapses under the uncapped state from when the switch 16 detects the uncapped state (measuring step).

When the USB memory 1 g is connected to the USB port 31 of the PC 30 g, the USB interface (connection detecting unit 12) 106 detects that the main body unit 10 g is connected (USB connection) to the USB port 31 of the PC 30 a, and the second timer 14 measures (countdowns) a time duration that elapses at a state in which the USB connector 17 is being connected to the PC 30 a.

When detecting the fifth predetermined time duration having been set beforehand elapses under the uncapped state, the first timer 13 outputs a fifth predetermined time duration detection signal to the copy controlling unit 22.

The copy controlling unit 22, which received the fifth predetermined time duration from the first timer 13, performs controlling such that the data stored in the storage unit 11 of the USB memory 1 g is copied (backed up) in the storage unit 32.

More precisely, the copy controlling unit 22 notifies the PC 30 g of the amount of information stored in the storage unit 11 together with inquiring the PC 30 g of the transmission destination of the data. The copy controlling unit 22 performs data transmission (copying) based on a response from the PC 30 g (copying step). Further, at that time, the transmission destination of the backup data and the amount of data transmitted (the transmission amount) are held in association with information identifying the transmitted data (for example, file name).

The PC 30 g stores the data transmitted from the USB memory 1 g in the storage unit 32 together with sending a signal (completion report) indicating that the transmission is completed, while the copy controlling unit 22 sets “1” to this backup transmission completion flag.

After that, the deleting unit 21 deletes the data stored in the storage unit 11 (deleting step), and sets “1” to the USB memory deletion completion flag with respect to the deleted data.

Further, when detecting the sixth predetermined time duration having been set beforehand elapses under an uncapped state, the first timer 13 outputs a sixth predetermined time duration detection signal to the deleting unit 21. When detecting the seventh predetermined time duration having been set beforehand elapses from when the USB connector 17 is connected to the PC 30 a, the second timer 14 also outputs a seventh predetermined time duration detection signal to the deleting unit 21.

Further, when detecting that the PC 30 g falls in an unused state thereof based on information or the like from the user detector 35, the unused state detector 34 outputs an unused state detection signal to the deleting unit 21.

Upon reception of the sixth predetermined time duration detection signal, the seventh predetermined time duration detection signal, or the unused state detection signal, the deleting unit 21 deletes data stored in the storage unit 11.

According to the PC 30 g, it is possible to evaluate whether or not backup of the data has been completed by means of referring to the backup transmission completion flag, and it is also possible to evaluate whether or not data deletion from the USB memory 1 g has been completed by means of referring to the USB memory deletion completion flag.

Further, at the time the copy controlling unit 22 makes data stored in the storage unit 11 to be copied to the storage unit 32 provided for the PC 30 g, the copy inhibitor 41 inhibits data copying by the copy controlling unit 22 to the storage unit 32 in a case where, for example, it is admitted that the PC 30 g is not the one which relates to specific related people having specific relationships with the USB memory 1 g, or that a user of the USB memory 1 g is not one of the specific related people having specific relationships with the USB memory 1 g.

Further, when deciding that a user of the PC 30 g is not one of the specific related people having specific relationship with the USB memory 1 g, the access inhibitor 42 inhibits accessing from the PC 30 g to the storage unit 11.

Further, when the copy controlling unit 22 restores the data, which is backed up in the storage unit 32 of the PC 30 g, in the USB memory 1 g, an operator, for example, inputs a restoring instruction through the keyboard 306 of the PC 30 g or the mouse 307.

In a case where such data instruction is issued, the USB memory 1 g obtains the destination of the data transmitted from the storage unit 11 and the amount of data. On the basis of such information, the USB memory 1 g obtains the data to be restored from the storage unit 32 and transmits the data to the USB memory 1 g (storage unit 11), thereby being capable of restoring the backed up data. In this manner, when data restoring is performed, the backup transmission completion flag and the USB memory deletion operation flag fall in the state of being “0”.

As described above, with the USB memory 1 g and the PC 30 g according to the fifth embodiment of the present invention, it is not only possible to obtain the effects and benefits similar to those of the second embodiment, but it is also possible to prevent the data stored in the USB memory 1 g from being lost since the data stored in the storage unit 11 of the USB memory 1 g is copied (backed up) in the storage unit 32 of the PC 30 g.

Further, at that time, the copy inhibitor 41 inhibits data copying by the copy controlling unit 22 to the storage unit 32 in a case where, for example, it is admitted that the PC 30 g is not the one which relates to specific related people having specific relationships with the USB memory 1 g or in a case it is admitted that a user of the USB memory 1 g is not one of the specific related people having specific relationships with the USB memory 1 g. Thus, the data stored in the storage unit 11 of the USB memory 1 g is never backed up in the PC 30 g when the third person illegally uses the USB memory 1 g or the PC 30 g. This makes it possible to prevent illegal use of the USB memory 1 g and the PC 30 g, so that the confidentiality of data can be improved.

Still further, the access inhibitor 42 inhibits accessing from the PC 30 g to the storage unit 11, when it is admitted that a user of the PC 30 g is not one of the specific related people having specific relationships with the PC 30 g. This also makes it possible to prevent illegal use of the data stored in the storage unit 11 in the USB memory 1 g, so that the confidentiality of data can be improved.

(H) Sixth Embodiment

FIG. 14 is a diagram schematically showing a functional construction of a USB (Universal Serial Bus) memory 1 h and a PC (information processing apparatus, computer) 30 h according to a sixth embodiment of the present invention.

Similar to the already described first embodiment, in the USB memory (electronic apparatus) 1 h and the PC 30 h according to the sixth embodiment, the USB connector (communication unit, connection terminal) 17 of the USB memory 1 h is inserted/connected to the USB connector (communication unit, connection terminal) 17 of the USB port 31, the USB memory 1 h being thereby connected to the PC 30 h in a communicable manner therebetween, and data reading, data writing, data deleting or the like in the storage unit 11 of the USB memory 1 h is performed from the PC 30 h.

As shown in FIG. 14, the PC 30 h according to the sixth embodiment includes: a copy controlling unit 22; a copy inhibitor 41; a deleting unit 21; an access inhibitor 42; a second timer 14; a connection detector 12; an unused state detector 34; and a user detector 35, which are provided for the main body unit 10 g of the USB memory 1 g according to the fifth embodiment shown in FIG. 13. Further, the PC 30 h is provided with an elapse time obtaining unit 43; a storage time limit setting unit 44; an alerting unit 37; and a managing unit 46.

Further, the main body unit 10 g has a cap (component; non-illustrated) having the similar construction to that of the cap 20 a of the USB memory 1 a according to the first embodiment, which cap is removable from the USB connector 17.

Here, in the figure, since the reference characters the same as those which are already described indicate the same or approximately the same parts, their detailed descriptions will be omitted.

In addition, similar to the PC 30 a according to the first embodiment, the PC 30 h according to the sixth embodiment has a hardware construction as shown in FIG. 3, and thus, its detailed description will be omitted.

The elapse time obtaining unit 43 obtains a time duration that elapses from when the latest access is made to data stored in the storage unit 11 or the storage unit 32. For example, the elapse time obtaining unit 43 manages dates and times at which data accesses are made, and measures an time duration that elapses from the time of this access by using a timer (not illustrated), and calculates an elapse time duration by means of obtaining a difference from the current time, thereby obtaining the elapse time duration.

The storage time limit setting unit 44 gives the data stored in the storage unit 11 or the storage unit 32 a time limitation of data storage therein.

Here, as a specific method for setting the specific storage time limitation, there are methods of such as making a management table in a dedicated area provided inside the USB memory 1 h to manage information (storage time limitation information) relating to the storage time limitation, and embedding the storage time limitation information in a standard file property information area of an OS (Operating System) such as Windows (registered trademark) With such methods, it is possible to set the storage limitation of the data.

In this manner, on the basis of the storage time limitation set to each data item, data whose storage time limit will come in the nearest future is extracted, and the storage time limit of this data is set to a timer (not illustrated).

Then, when a notification that the storage time limit has run out is notified by this timer, the data is deleted, and then, the storage time limit of data whose storage time limit will come in the next place is newly set to the timer. Here, in a case where there are data items whose storage time limits are the same, such storage time limits can be set with some deviation thereof.

Further, setting of the storage time limitation to the timer can be performed by using a dedicated command to the USB memory 1 h, or by diverting the data writing in the dedicated area, and various types of methods can be used.

In this instance, to realize the above methods, it is preferable to provide the PC 30 h with software for managing storage time limits, and also to provide the USB memory 1 h with firmware for management.

When detecting an eighth predetermined time duration (second predetermined time duration) having been set beforehand elapses from when the connection detector 12 detects that the USB connector 17 is connected to the PC 30 h, the second timer 14 outputs a signal indicating as such (an eighth predetermined time duration detection signal) to the alerting unit 37. Further, when detecting a ninth predetermined time duration (first predetermined time duration) having been set beforehand elapses from when the connection detector 12 detects that the USB connector 17 is connected to the PC 30 h, the second timer 14 outputs a signal indicating as such (a ninth predetermined time duration detection signal) to the deleting unit 21.

The alerting unit 37 gives an alert in a case where any of the elapse time durations, obtained by the elapse time obtaining unit 43, of the data stored in the storage unit 11 or the storage unit 32 is longer (the storage time limit has been out) than the storage time limit set by the storage time limit setting unit 44.

Further, the alerting unit 37 gives an alert when it receives the eighth predetermined time duration detection signal from the second timer 14.

In this instance, similar to in the USB memory 1 e according to the third embodiment, this alerting unit 37 gives an alert when the timer 13 detects that the sixth predetermined time duration (second predetermined time duration), having been set beforehand, elapses.

Further, the alerting unit 37 may give an alert when the first timer 13 detects that a time duration, that elapses under the uncapped state from when the cap 20 f is uncapped from the USB connector 17, is longer than a predetermined time duration.

Still further, in the PC 30 h according to the sixth embodiment, the deleting unit 21 deletes an item of data stored in the storage unit 11 or the storage unit 32 in a case where the elapse time duration of the data item, which elapse time duration is obtained by the elapse time obtaining unit 43, is longer than the predetermined storage limit, set by the storage time limit setting unit 44, by the ninth predetermined time duration (the first predetermined time duration).

Further, the above described storage time limit and predetermined time duration for the deleting unit 21 to perform deletion can be arbitrarily set by a user through the keyboard 306 or the like.

The managing unit 46 registers beforehand therein information identifying the USB memory 1 h for managing the information, and it registers beforehand therein information (identification information) identifying the USB memory 1 h which is permitted to be connected to the PC 30 h.

More precisely, a registration system for the USB memory 1 h is previously employed. The managing unit 46 assigns a management number and/or a management ID (IDentification) beforehand to the USB memory 1 h which is permitted to be connected to the PC 30 h, and the managing unit 46 manages them in the form of a management table.

Then, referring to this managing unit 46 (management table), the alerting unit 37 gives an alert at the time a USB memory 1 h which is not managed by the managing unit 46 is connected to the USB port 31.

In the PC 30 h according to the sixth embodiment having the above described construction, when the USB memory 1 h is connected to the USB port 31, the data stored in the storage unit 11 is searched in terms of whether or not there is information to be managed such as the above described storage time limitation and a predetermined time duration for performing deletion or the like.

Here, in a case where there is data to which a storage time limit and/or a predetermined time duration for performing deletion are set, the elapse time obtaining unit 43 or the like evaluates if the storage time limit has been out. If the storage time limit is out, the alerting unit 37 makes an alert.

Further, in a case where there is an data item whose elapse time duration obtained by the elapse time obtaining unit 43 is longer than the storage time limit by a length not shorter than a predetermined time duration (the ninth predetermined time duration), the deleting unit 21 deletes the data item.

Further, when the USB memory 1 h is connected to the USB port 31, the PC 30 h obtains the identification information of this USB memory 1 h through the USB connector 17 and the USB port 31. When it is detected that the USB memory 1 h connected to the USB port 31 is not managed in the managing unit 46 with reference to this managing unit 46, the alerting unit 37 gives an alert.

Further, it can also be performed to inhibit access to the HDD 305 or the like in the PC 30 h, or to make the inserted USB memory not usable as well as giving an alert by the alerting unit 37.

Here, in the PC 30 h, even when the USB memory 1 h connected to the USB port 31 is the one which is managed by the managing unit 46, the second timer 14 measures a time duration that elapses from when an USB memory 1 h is connected to the USB port 31, and an alert is given when it is detected that the eighth predetermined time duration elapses. With this arrangement, it is possible for the USB memory 1 h to prevent the USB memory 1 h from being left in a state in which it is connected to the USB port 31 of the PC 30 h.

In this manner, with the USB memory 1 h and the PC 30 h according to the sixth embodiment, not only the effects and benefits of the fifth embodiment are realized but it is also possible to improve the confidentiality of data by means of deleting data whose storage time limit has been run out if such data is present, thereby preventing the leakage of such data. This makes it possible to improve the confidentiality of the data.

Further, since an alert is given when there is data whose storage time limit has been out, it is possible to notifies an operator of such, thereby making it possible for the operator to perform the optimal processing to the data, such as deletion of the data, so that the confidentiality of data is improved and high convenience is also realized.

Still further, when a USB memory 1 h which is not registered (non-registered) is connected to the USB port 31, the alerting unit 37 alerts the alerting unit 37. Thus, for example, it is possible to prevent a third person from obtaining the data stored in the PC 30 h by using such an unregistered USB memory 1 h, and so that the confidentiality of the information stored in the PC 30 h is improved.

(I) Others

Here, the CPU (Central Processing Unit) of the information processing apparatus (PCs 30 a, 30 e, 30 g, and 30 h) executes a management program, thereby functioning as the copy controlling unit 22, the access inhibitor 42, the copy inhibitor 41, the deleting unit 21, the elapse time obtaining unit 43, the storage time limit setting unit 44, the copy inhibitor 41, the deleting unit 21, the elapse time obtaining unit 43, the storage time limit setting unit 44, the managing unit 46, the unused state detector 34, the user detector 35, the user confirming unit 38, the USB memory confirming unit 40, and the alert controller 33, which are already described.

In this instance, programs (management programs) for realizing the functions of these copy controlling unit 22, access inhibitor 42, copy inhibitor 41, deleting unit 21, elapse time obtaining unit 43, storage time limit setting unit 44, managing unit 46, unused state detector 34, user detector 35, user confirming unit 38, USB memory confirming unit 40, and alert controller 33, is offered in the form of computer-readable recording media such as flexible discs, CDs (CD-ROMs, CD-Rs, and CD-RWs), and DVDs (DVD-ROMs, DVD-RAMs, DVD-Rs, DVD+Rs, DVD-RWs, and DVD+RWs) The computer reads the programs from such recording media to transfer the programs to an internal or external storage device, which stores the program therein. Alternatively, the programs can be recorded in storage devices (recording media) such as magnetic discs, optical discs, and magneto-optical discs, to be transferred to the computer over a communication network. The computer reads the programs from such recording media to transfer the program to an internal or an external storage device, to store the program therein. Alternatively, the programs can be recorded in storage devices (recording media) such as magnetic discs, optical discs, and magneto-optical discs, to be transferred to the computer over a communication network.

At the time of realizing the functions of the copy controlling unit 22, the access inhibitor 42, the copy inhibitor 41, the deleting unit 21, the elapse time obtaining unit 43, the storage time limit setting unit 44, the managing unit 46, the unused state detector 34, the user detector 35, the user confirming unit 38, the USB memory confirming unit 40, and the alert controller 33, the programs stored in the internal storage apparatus (for example, the RAM 303 and the ROM 302) are executed by the microprocessor (the CPU 301 in the present embodiment). At that time, the programs recorded in such recording medium can be read by the computer which then executes those read-out programs.

Here, the “computer” is defined as a concept including hardware and an OS (Operating System), or hardware operating under control of an OS. Further, in cases where hardware is capable of operating by itself without the necessity of an OS, the hardware is equivalent to the “computer.” The hardware includes at least a microprocessor such as a CPU and a means for reading computer programs from recording media. In the present embodiment, the PCs 30 a, 30 e, 30 g, and 30 h have functions as computers.

Further, as recording media used in the embodiments of the present invention, not only the above-mentioned flexible discs, CDs, DVDs, magnetic discs, optical discs, and magneto-optical discs, but also various types of other computer-readable media, such as IC cards, ROM cartridges, magnetic tapes, punch cards, internal storage devices (memories such as a RAM and a ROM) of the computer, external storage devices, and printed matter with any codes such as barcodes printed thereon, are also applicable.

Still further, the processors 102 of the USB memories 1 a through 1 g execute the USB memory management program stored in the inner storage apparatus (for example, the RAM 103 and the control soft ROM 104), thereby functioning as the copy controlling unit 22, the access inhibitor 42, the copy inhibitor 41, the deleting unit 21, the elapse time obtaining unit 43, the storage time limit setting unit 44, the managing unit 46, the unused state detector 34, the user detector 35, the user confirming unit 38, the USB memory confirming unit 40, and the alert controller 33.

Yet further, the present invention should by no means be limited to the above-illustrated embodiments, and various changes or modifications may be suggested without departing from the gist of the invention.

For example, in the above described first embodiment, third to fifth embodiments, and modified examples of these embodiments, the alerting unit 15 is formed by the buzzer circuit 108 which generates an alarming sound at a specific frequency, thereby giving a user an alert that acts on the auditory sense. However, the present invention should by no means be limited to this, and an alert can be given by a variety of kinds of methods which give various kinds of stimulations to the senses (the senses of seeing, touching, tasting, and smelling) such as generating a vibration by a vibration generating circuit and turning on a light.

In addition, the alerting unit 15 according to the first embodiment 1 a can be provided for the USB memory 1 d. When the first timer 13 detects elapse of the first predetermined time duration and when the second timer 14 detects elapse of the second predetermined time duration, the alerting unit 15 gives an alert prior to deletion of the data stored in the storage unit 11 by the deleting unit 21, thereby notifying a user that data deletion will be performed. This makes it possible for a user to previously know that the data stored in the storage unit 11 will be deleted, so that high convenience is realized.

Further, the alerting unit 15 and the battery measuring unit 18 according to the first embodiment 1 a can be provided for the USB memory 1 d of the second embodiment. When the battery measuring unit 18 detects that the remaining battery amount of the battery 19 becomes not larger than the predetermined amount, the alerting unit 15 gives an alert. This makes it possible for a user to know that the remaining battery amount has become small, so that high convenience is realized.

Still further, in the USB memories 1 g and 1 h according to the fifth embodiment and the sixth embodiment, respectively, when the unused state detector 34 detects transition of the PC 30 g, 30 h into an unused state thereof, the copy controlling unit 22 may make the data stored in the storage unit 11 to be copied in the storage unit 32 of the PC 30 g, 30 h, and may back up the data stored in the storage unit 11 of the USB memory 1 g, 1 h and then delete the data from the storage unit 11 of the USB memory 1 g, 1 h.

Here, the unused state detector 34 may detect the transition of the PCs 30 g, 30 h into the unused state thereof by means of detecting power breakage of the PC 30 g, 30 h or by means of detecting shift of the PC 30 g, 30 h to a power-saving operation mode.

Further, in the above described embodiments and modified examples of these embodiment, a description is made of an example in which the electronic apparatus is a USB memory. However, the present invention should by no means be limited to this, and the electronic apparatus can be, for example, an electronic apparatus that supports another communication protocol and/or bus standard regulations such as the IEEE 1394 (FireWire) regulations. In addition, the present invention can be applied to electronic apparatuses other than a memory. In this instance, like the USB, this IEEE 1394 can supply power with bus power.

Further, in the above described embodiments and modified examples of these embodiment, a description is made of an example in which a component is the cap of a USB memory. However, the present invention should by no means be limited to this, and a case that accommodates therein a USB memory the other types of portable recording apparatuses, and the main bodies of the electronic apparatuses other than a memory, is also a component included in the present invention.

Still further, in the above described embodiments, and the modified examples of these embodiments, a description is made of an example in which the communication unit of the electronic apparatus is a connection terminal which is electrically coupled to the information processing apparatus. However, the present invention should by no means be limited to this, and this communication unit can be the one which makes possible wireless communication between the electronic apparatus and the information processing apparatus. In this case, also, the connection unit of the information processing apparatus can be formed by the one which is capable of performing radio communication with the electronic apparatus.

Yet further, in the above described embodiments and modified examples of these embodiment, at least some of the first through seventh predetermined time durations may be set by a user arbitrarily.

Furthermore, a description is made of an example in which the PC 30 h shown in the sixth embodiment is provided with the elapse time obtaining unit 43 and the storage time limit setting unit 44. However, the present invention should by no means be limited to this, and an elapse time obtaining unit 43 and a storage time limit setting unit 44 can be provided for the USB memories 1 a, 1 b, 1 c, 1 d, 1 e, 1 f, and 1 g, and the PCs 30 a, 30 e, 30 g, and 30 h, according to the other embodiments and their modified examples.

Moreover, in the USB memory 1 d according to the second embodiment, the USB memory 1 g according to the fifth embodiment, and the USB memory 1 h according to the sixth embodiment, the battery measuring unit 18 can be provided for the battery 19. When the battery measuring unit 18 detects that the remaining battery amount in the battery 19 becomes not larger than a predetermined value, the alerting unit 15 gives an alert.

Here, with the disclosure of each of the embodiments of the present invention, it is possible for the ordinarily skilled in the art to implement and manufacture the present invention.

INDUSTRIAL APPLICABILITY

The present invention is applicable to management of a variety of kinds of electronic apparatuses that are connected to an information processing apparatus in a communicable manner therebetween with various types of regulations such as the USB and the IEEE 1394 (FireWire). 

1. An information processing apparatus, comprising: a connection unit which an electronic apparatus is adapted to be communicably coupled to; a connection detecting unit which detects coupling of the electronic apparatus to said connection unit; a timer which measures a time duration that elapses under a connection state, in which the electronic apparatus is coupled; and an alerting unit which alerts a user of the information processing apparatus when it is detected by said timer that a predetermined time duration elapses.
 2. An information processing apparatus as set forth in claim 1, further comprising: an alert controlling unit which is capable of restraining the alert given by said alerting unit, said alert controlling unit restraining the alert given by said alerting unit, if a user of the information processing apparatus is a specific authorized user relating to the information processing apparatus when said timer detects that the predetermined time duration elapses.
 3. An information processing apparatus as set forth in claim 1, further comprising: an unused state detecting unit which detects transition of the information processing apparatus to an unused state thereof by the user, said alerting unit giving the alert when said unused state detecting unit detects the transition of the information processing apparatus to the unused state thereof.
 4. An information processing apparatus as set forth in claim 3, said unused state detecting unit detecting the transition of the information processing apparatus to the unused state thereof by means of detecting power-off of the information processing apparatus.
 5. An information processing apparatus as set forth in claim 3, said unused state detecting unit detecting the transition of the information processing apparatus to the unused state thereof by means of detecting shifting of the information processing apparatus into a power-saving operation mode.
 6. An information processing apparatus as set forth in claim 3, further comprising: a user detecting unit which detects existence of a user of the information processing apparatus, said unused state detecting unit detecting the transition of the information processing apparatus to the unused state thereof at the time the existence of the detected user is not anymore detected by said user detecting unit.
 7. An information processing apparatus as set forth in claim 1, further comprising: a first user confirming unit which confirms that a user of the information processing apparatus is the specific authorized user relating to the information processing apparatus.
 8. An information processing apparatus as set forth in claim 2, said alert controlling unit restraining an alert given by said alerting unit when the electronic apparatus coupled to the information processing apparatus is an electronic apparatus of the specific authorized user.
 9. A managing method for use in an information processing apparatus including a connection unit which an electronic apparatus is adapted to be communicably coupled to, said method comprising: (a) detecting coupling of the electronic apparatus to the connection unit; (b) measuring an elapse time duration that elapses under a connection-established state, in which the electronic apparatus is coupled to the electronic apparatus, from when the connection with the electronic apparatus is detected in said step (a); and (c) giving a user of the information processing apparatus an alert when it is detected that a predetermined time duration that elapses in said step (b).
 10. A managing method as set forth in claim 9, further comprising: (d) restraining the alert given in said step (c), wherein, in said step (d), the alert given in said step (c) is restrained, if a user of the information processing apparatus is confirmed to be a specific authorized user relating to the information processing apparatus when it is detected that the predetermined time duration elapses in said step (b).
 11. A managing method as set forth in claim 9, further comprising: (e) detecting transition of the information processing apparatus to an unused state thereof by the user, wherein the alert is given in said step (c) when the transition of the information processing apparatus to an unused state thereof is detected in said step (e).
 12. A managing method as set forth in claim 11, wherein, in said step (e), the transition of the information processing apparatus to the unused state thereof is detected by means of detecting power-off of the information processing apparatus.
 13. A managing method as set forth in claim 11, wherein, in said step (e), the transition of the information processing apparatus to the unused state thereof is detected by means of detecting shifting of the information processing apparatus into a power-saving operation mode.
 14. A managing method as set forth in claim 11, further comprising: (f) detecting existence of a user of the information processing apparatus, wherein the transition of the information processing apparatus to the unused state thereof is detected in said step (e) at the time the existence of the user detected in said step (f) is not detected anymore.
 15. A managing method as set forth in claim 11, further comprising: (g) confirming that a user of the information processing apparatus is the specific authorized user.
 16. A computer-readable recording medium in which a managing program for a computer to execute a managing function is recorded, wherein the program instructs the computer, having a connection unit to which an electronic apparatus is adapted to be communicably coupled, to execute the steps of: (a) detecting coupling of the electronic apparatus to the connection unit; (b) measuring an elapse time duration that elapses under a connection-established state, in which the electronic apparatus is coupled to the electronic apparatus, from when the connection with the electronic apparatus is detected in the step (a); and (c) giving a user of the information processing apparatus an alert when it is detected that a predetermined time duration elapses in the step (b).
 17. An electronic apparatus having a communication unit for communicably coupling the electronic apparatus to an information processing apparatus, said electronic apparatus comprising: a connection detecting unit which detects coupling of the electronic apparatus to the information processing apparatus via the communication unit; a timer which measures an elapse time duration that elapses under a connection-established state, in which the electronic apparatus is coupled to the information processing apparatus, from when said connection detecting unit detects the connection of the communication unit to the information processing apparatus; and an alerting unit which gives a user of the electronic apparatus an alert when it is detected by said timer that a predetermined time duration elapses.
 18. An electronic apparatus as set forth in claim 17, further comprising: an alert controlling unit which is capable of restraining the alert given by said alerting unit, said alert controlling unit restraining the alert given by said alerting unit, if a user of the information processing apparatus is a specific authorized user relating to the electronic apparatus when said timer detects that the predetermined time duration elapses.
 19. An electronic apparatus as set forth in claim 18, further comprising: a user confirming unit which confirms that a user of the information processing apparatus is a specific authorized user relating to the information processing apparatus.
 20. An electronic apparatus as set forth in claim 18, said alert controlling unit restraining the alert given by said alerting unit in a case where the electronic apparatus is an electronic apparatus of the specific authorized user. 